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s6e1b3 series 32 - bit arm ? cortex ? - m 0+ fm 0+ microcontroller cypress semiconductor corporation ? 198 champion court ? san jose , ca 95134 - 1709 ? 408 - 943 - 2600 document number: 001 - 99224 rev.** revised august 31, 2015 preliminary the s6e1 b3 series is a series of highly integrated 32 - bit microcontrollers designed for embedded controllers aiming at low power consumption and low cost . th is s eries has the arm cortex - m0+ processor with on - chip flash memory and sram, and consists of peripheral functions such as various t imers, adc and c ommunication i nterfaces (uart, c sio (spi), i 2 c , i 2 s, smart card, and usb). the products which are described in this data sheet are placed into type 2 - m0+ product categories in "fm 0+ family peripheral manual ". features 32 - bit arm cortex - m0+ core ? processor version: r 0 p1 ? maximum operating frequency: 40 .8 mhz ? nested vectored interrupt controller (nvic): 1 nmi (non - maskable interrupt) and 24 peripheral interrupt with 4 selectable interrupt priority levels ? 24 - bit system timer (sys t ick): system timer for os task management bit band operation compatible with cortex - m3 bit band operation. on - chip memor y ? flash memory ? up to 512 k+48 kbyte s ? dual bank ? upper bank : 512 kbytes(64 kbytes x 8) ? lower bank : 48 kbytes(8k bytes x 6) ? read cycle: 0 wait - cycle ? security function for code pro tection ? sram th e on - chip sram of this series has o ne independent sram . ? up to sram : 60 k+4 kbytes ? 4kbytes: can retain value in d eep standby mode usb interface usb interface is composed of device and host pll for usb is built - in, usb clock can be generated by multiplication of main clock. ? usb device ? usb 2.0 full - speed supported ? max 6 endpoint supported ? endpoint 0 is control transfer ? endpoint 1, 2 can be selected bulk - transfer, interrupt - transfer or isochronous - transfer ? endpoint 3 to 5 can select bulk - transfe r or interrupt - transfer ? endpoint 1 to 5 comprise double buffer ? the size of each endpoint is according to the follows ? endpoint 0, 2 to 5 : 64 bytes ? endpoint 1 : 256 bytes ? usb host ? usb 2.0 full/low - speed supported ? bulk - transfer, interrupt - transfer and isochronous - transfer support ? usb device connected/disconnected automatically detect ? in/out token handshake packet automatically ? max 256 - byte packet - length supported ? wake - up function supported multi - function s erial i nterface (max 8 channels ) ? 128 byte s with t x/rx fifo in all channels ( t he number of fifo ste ps varies depending on the settings of the communication mode or bit length.) ? the operation mode of each channel can be selected from one of the following. ? uart ? csio (csio is known to many customers as spi) ? i 2 c ? uart ? full duplex double buffer ? parity can be enabled or disable d . ? built - in dedicated baud rate generator ? external clock available as a serial clock ? various error detection functions (parity errors, framing errors, and overrun errors) ? csio (also known as spi) ? full duplex double buffer ? built - in dedicated baud rate generator ? overrun error detection function ? serial chip select function (ch 1 and ch 3 only) ? data length : 5 to 16 bit s ? i 2 c ? standard - mode (max : 100 kbps) supported / fast - mode (max 400 kbps) supported . ? i 2 s ? using csio (ch.5, ch.6) and i 2 s clock generator ? supports two transfer protocol ? i 2 s ? msb - justified ? master mode only
document number: 001 - 99224 rev.** page 2 of 115 s6e1b3 series preliminary descriptor system data transfer contr oller ( dstc ) (64 channels ) ? the dstc can transfer data at high - speed without going via the cpu. the dstc adopts the descriptor ? system and, following the specified contents of the descriptor that has already been constructed on the ? memory, can access directly the memory / peripheral device and performs the data transfer operation. ? it supports the software activation, the hardware activation , and the chain activation functions a/d converter (max : 24 channels ) ? 12 - bit a/d converter ? successive a pproximation type ? conversion time: 2.0 s @ 2.7 v to 3.6 v ? priority conversion available ( 2 levels of priority) ? scan conversion mode ? built - in fifo for conversion data storage (for scan conversion: 16 steps, for p riority conversion: 4 steps) base timer (max : 8 channels ) the operation mode of each c hannel can be selected from one of the following. ? 16 - bit pwm timer ? 16 - bit ppg timer ? 16/32 - bit reload timer ? 16/32 - bit pwc timer general - purpose i/o port this series can use its pin as a general - purpose i/o port when it is not used for an external bus or a peripheral function. all ports can be set to fast general - purpose i/o ports or slow general - purpose i/o ports. in addition, this series has a port relocate function that can set to which i/o port a peripheral function ca n be allocated. ? all ports are fast g pio which can be accessed by 1cycle ? capable of controlling the pull - up of each pin ? capable of reading pin level directly ? p ort relocate function ? up to 102 fast general - purpose i/o p orts @ 120 - pin p ackage ? certain ports are 5 v tolerant . see 4 . list of pin functions and 5 . i /o circuit type for the corresponding pins. dual timer (32 - /16 - bit down counter) the dual timer consists of two programmable 32 - /16 - bit down counters. the operation mode of each timer channel can be selected from one of the following. ? free - run ning mode ? periodic mode (= reload mode ) ? one - shot mode multi - function t imer the m ulti - function t imer consists of the following blocks. ? 16 - bit free - run timer 3 ch annels ? input capture 4 ch annels ? output compare 6 ch annels ? a dc start compare 6 ch annel ? waveform generator 3 ch annels ? 16 - bit ppg timer 3 ch annels igbt mode is contained. the following function can be used to achieve the motor control. ? pwm signal output function ? dc chopper waveform output function ? dead time function ? input capture function ? ad c start function ? dtif ( m otor emergency stop) interrupt function real - time c lock (rtc with vbat) the real - time c lock count s y ear/ m onth/ d ay/ h our/ m inute/ s econd/ d ay of the week from year 01 to year 99. ? the rtc can ge nerate an interrupt at a specific time (y ear/ m onth/ d ay/ h our/ m inute/ s econd/ d ay of the week ) and can also generate an interrupt in a specific year, in a specific month, on a specific day, at a specific hour or at a specific minute. ? it has a timer interrupt function generating an interrupt upon a specific time or at specific intervals. ? it can keep counting while rewriting the time. ? it can count leap years automatically. watch counter the watch c ounter wake s up the microcontroller from the low power consumptio n mode. the clock source can be selected from the main clock, the sub clock, the built - in high - speed cr clock or the built - in low - speed cr clock. interval timer: up to 64 s (s ub c lock : 32.768 khz ) external interrupt controller unit ? up to 24 external i nterr upt input pins ? n on - m askable interrupt (nmi) input pin : 1 watchdog t imer (2 channels ) the watchdog timer generate s an interrupt or a reset when the counter reaches a time - out value. this series consists of two different watchdogs, h ardware watchdog and s oftware watchdog. the h ardware watchdog timer is clocked by the built - in low - speed cr oscillator. therefore , the h ardware watchdog is
document number: 001 - 99224 rev.** page 3 of 115 s6e1b3 series preliminary active in any low - power consumption modes except rtc, stop, deep standby rtc and deep standby stop mode. crc (cyclic redun dancy check) accelerator the crc accelerator calculates the crc which has a heavy software processing load, and achieves a reduction of the integrity check processing load for reception data and storage. ? ccitt crc16 and ieee - 802.3 crc32 are supported. ? ccit t crc16 generator polynomial: 0x1021 ? ieee - 802.3 crc32 generator polynomial: 0x04c11db7 hdmi - cec/remote control receiver (up to 2 channels) ? hdmi - cec transmitter ? header block automatic transmission by judging signal free ? generating status interrupt by detecting arbitration lost ? generating start, eom, ack automatically to output cec transmission by setting 1 byte data ? generating transmission status interrupt when transmitting 1 block (1 byte data and eom/ack) ? hdmi - cec receiver ? automatic ack reply functio n available ? line error detection function available ? remote control receiver ? 4 bytes reception buffer ? repeat code detection function available smart card interface ? compliant with iso7816 - 3 specification ? card reader only/b class card only ? available protocol s ? transmitter: 8e2, 8o2, 8n2 ? receiver: 8e1, 8o1, 8n2, 8n1, 9n1 ? inverse mode ? tx/rx fifo integrated (rx: 16 - bytes, tx:16 - bytes) clock and reset ? clocks a clock can be selected from five clock sources ( two external oscillator s, two built - in cr oscillator , and m ain pll). ? main c lock: 4 mhz to 4 0 mhz ? sub c lock : 32.768 khz ? built - in high - speed cr c lock : 4 mhz ? built - in low - speed cr c lock : 100 khz ? main pll c lock ? resets ? reset request from the initx pin ? power on reset ? software reset ? watchdog timer reset ? low - voltage detection reset ? clock s uper v isor reset clock super v isor (csv) the clock supervisor monitors the failure of external clocks with a clock generated by a built - in cr oscillator. ? if an e xternal clock failure (clock stop) is detected, a reset is ass erted. ? if an e xternal frequency anomaly is detected, an interrupt or a reset is asserted. low - voltage detector (lvd) this s eries monitors the voltage on the vcc pin with a 2 - stage mechanism. when the voltage falls below a designated voltage, the low - voltage detector generates an interrupt or a reset. ? lvd r : monitor v cc and auto - reset operation ? lvd1: monitor v cc and error report ing via an interrupt ? lvd2: selectable to monitor v cc or lvdi and error reporting via an interrupt low power consumption m ode this series has six low power consumption modes. ? sleep ? timer ? rtc ? stop ? deep standby rtc (selectable between keeping the value of ram and not) ? deep standby stop (selectable between keeping the value of ram and not) peripheral clock gating the system can reduce the current consumption of the total system with gating the operation clocks of peripheral functions not used. vbat the consumption power during the rtc operation can be reduced by supplying the power supply independent vbat pin . rtc (calendar circuit) / 32 khz oscillation circuit. the following circuit can also be used. ? rtc ? 32 khz oscillation circuit ? power - on circuit ? back up register: 32 bytes ? port circuit debug ? serial wire debug port (sw - dp) ? micro trace buffer (mtb) unique id a 41 - bit unique value of the device has been set.
document number: 001 - 99224 rev.** page 4 of 115 s6e1b3 series preliminary power supply ? wide voltage range : vcc = 1.65 v to 3.6 v vcc = 3.0v to 3.6v (when usb is used) ? power supply for vbat: vbat = 1.65 v to 3.6 v
document number: 001 - 99224 rev.** page 5 of 115 s6e1b3 series preliminary table of contents features ................................ ................................ ................................ ................................ ................................ ................... 1 1. product lineup ................................ ................................ ................................ ................................ ............................... 7 2. packages ................................ ................................ ................................ ................................ ................................ ......... 8 3. pin assignment ................................ ................................ ................................ ................................ .............................. 9 4. list of pin functions ................................ ................................ ................................ ................................ .................... 12 5. i/o circuit type ................................ ................................ ................................ ................................ ............................. 35 6. handling precautions ................................ ................................ ................................ ................................ .................. 40 6.1 precautions for product design ................................ ................................ ................................ ................................ ... 40 6.2 precautions for package mounting ................................ ................................ ................................ .............................. 41 6.3 precautions for use environment ................................ ................................ ................................ ................................ 43 7. handling devices ................................ ................................ ................................ ................................ ......................... 44 8. block diagram ................................ ................................ ................................ ................................ .............................. 47 9. memory map ................................ ................................ ................................ ................................ ................................ . 48 10. pin status in each cpu state ................................ ................................ ................................ ................................ ...... 51 11. electrical characteristics ................................ ................................ ................................ ................................ ............ 58 11.1 absolute maximum ratings ................................ ................................ ................................ ................................ ......... 58 11.2 recommended operating conditions ................................ ................................ ................................ .......................... 59 11.3 dc characteristics ................................ ................................ ................................ ................................ ....................... 60 11.3.1 current rating ................................ ................................ ................................ ................................ .............................. 60 11.3.2 pin characteristics ................................ ................................ ................................ ................................ ....................... 65 11 .4 ac characteristics ................................ ................................ ................................ ................................ ....................... 66 11.4.1 main clock input characteristics ................................ ................................ ................................ ................................ .. 66 11.4.2 sub clock input characteristics ................................ ................................ ................................ ................................ ... 67 11.4.3 built - in cr oscillation characteristics ................................ ................................ ................................ .......................... 68 11.4.4 operating conditions of main pll (in the case of using the main clock as the input clock of the pll) .................... 69 11.4.5 operating conditions of main pll (in the case of using the built - in high - speed cr clock as the input clock of the main pll) ................................ ................................ ................................ ................................ ........ 69 11.4.6 reset input characteristics ................................ ................................ ................................ ................................ .......... 70 11.4.7 power - on reset timing ................................ ................................ ................................ ................................ ................ 70 11.4.8 base timer input timing ................................ ................................ ................................ ................................ .............. 71 11.4.9 csio/spi/uart timing ................................ ................................ ................................ ................................ ............... 72 11.4.10 external input timing ................................ ................................ ................................ ................................ ................ 89 11.4.11 i 2 c timing ................................ ................................ ................................ ................................ ................................ . 90 11.4.12 i 2 s timing ................................ ................................ ................................ ................................ ................................ . 91 11.4.13 sm art card interface characteristics ................................ ................................ ................................ ........................ 92 11.4.14 sw - dp timing ................................ ................................ ................................ ................................ .......................... 93 11.5 12 - bit a/d converter ................................ ................................ ................................ ................................ .................... 94 11.6 usb characteristics ................................ ................................ ................................ ................................ .................... 97 11.7 low - voltage detection characteristics ................................ ................................ ................................ ...................... 102 11.7.1 low - voltage detection reset ................................ ................................ ................................ ................................ ..... 102 11.7.2 low - voltage detection interrupt ................................ ................................ ................................ ................................ . 103 11.7.3 low - voltage detection interrupt 2 ................................ ................................ ................................ .............................. 104 11.8 flash memory write/erase characteristics ................................ ................................ ................................ ............... 105 11.9 return time from low - power consumption mode ................................ ................................ ................................ .... 106 11.9.1 return factor: interrupt/wkup ................................ ................................ ................................ ................................ .. 106 11.9.2 return factor: reset ................................ ................................ ................................ ................................ .................. 108
document number: 001 - 99224 rev.** page 6 of 115 s6e1b3 series preliminary 12. ordering information ................................ ................................ ................................ ................................ ................. 110 13. package dimensions ................................ ................................ ................................ ................................ ................. 111 document history ................................ ................................ ................................ ................................ ............................... 114 sales, solutions, and le gal information ................................ ................................ ................................ ........................... 115
document number: 001 - 99224 rev.** page 7 of 115 s6e1b3 series preliminary 1. product lineup memory size product name s6e1b 3 4e / f / g s6e1b 3 6e / f / g on - chip flash memory upper bank 256 kbyte s 512 kbyte s lower bank 48 kbyte s 48 kbyte s on - chip s ram 32 kbyte s 64 kbyte s function product name s6e1b 3 4e 0a s6e1b 3 6e 0a s6e1b 3 4 f0a s6e1b 3 6 f0a s6e1b 3 4 g0a s6e1b 3 6 g0a pin count 80 100 120 cpu cortex - m0+ freq uency 40.8 mhz power supply voltage range 1.65 v to 3.6 v usb 2.0 ( device /host) 1 unit dstc 64 ch multi - function serial interface (uart/csio (spi) /i 2 c /i 2 s ) 8 ch (max) with 128 bytes fifo i 2 s: ch.5, ch.6 base timer (pwc/reload timer/pwm/ppg) 8 ch (max) m ulti - function timer a/d activation compare 6 ch 1 unit input capture 4 ch free - run timer 3 ch output compare 6 ch waveform generator 3 ch ppg 3 ch dual timer 1 unit hdmi - cec/ remote control receiver 2 ch (max) smart card interface 2 unit s real - time clock 1 unit (with battery power) watch counter 1 unit crc accelerator yes watchdog timer 1 ch (sw) + 1 ch (hw) external interrupt 24 pins (max) , nmi 1 i/o port 65 pins (max) 82 pins (max) 10 2 pins (max) 12 - bit a/d converter 16 ch ( 1 unit) 23 ch ( 1 unit) 24 ch (1 unit) csv (clock super v isor) yes lvd (low - v oltage detect ion ) 2 ch built - in cr high - speed 4 mhz low - speed 100 khz debug function sw - dp unique id yes note: ? all signals of the peripheral function in each product cannot be allocated by limiting the pins of package. it is necessary to use the port relocate function of the i/o port according to your function use. see " 11 . electrical characteristics 11.4 ac characteristics 11.4.3 built - in cr oscillation characteristics " for accuracy of built - in cr.
document number: 001 - 99224 rev.** page 8 of 115 s6e1b3 series preliminary 2. packages product name package s6e1b 3 4e/ s6e1b 3 6e s6e1b 3 4f/ s6e1b 3 6f s6e1b 3 4g/ s6e1b 3 6g lqfp : fpt - 80p - m21 ( 0.50 mm pitch) ? ? ? ? ? ? : available note: ? see " 13 . package dimensions " for detailed information on each package.
document number: 001 - 99224 rev.** page 9 of 115 s6e1b3 series preliminary 3. pin assignment fpt - 80p - m 21 (top view) note: ? the number after the underscore ("_") in a pin name such as xxx_1 and xxx_2 indic ates the relocated port number. the channel on such pin has multiple functions, each of which has its own pin name. use the e xtended p ort f unction r egister (epfr) to select the pin to be used . 80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 vcc 1 60 p21/an18/sin0_0/int06_1/wkup2 p50/int00_0/sin3_1 2 59 p22/an17/sot0_0/tiob7_1 p51/int01_0/sot3_1 3 58 p23/an16/sck0_0/tioa7_1/rto00_1 p52/int02_0/sck3_1 4 57 p1b/an11/sot4_1/ic02_1/int20_2 p53/sin6_0/tioa1_2/int07_2 5 56 p1a/an10/sin4_1/ic01_1/int05_1 p54/sot6_0/tiob1_2/int18_1 6 55 p19/an09/sck2_2/ic00_1 p55/sck6_0/adtg_1/int19_1 7 ` 54 p18/an08/sot2_2 p56/int08_2/mi2smck6_1/wkup9/cec1_1 8 53 avrh p30/tiob0_1/scs60_1/int03_2/mi2sws6_1/wkup4 9 52 avrl p31/tiob1_1/sck6_1/mi2sck6_1/int04_2 10 51 avss p32/tiob2_1/sot6_1/mi2sdo6_1/int05_2 11 50 avcc p33/int04_0/tiob3_1/sin6_1/mi2sdi6_1/adtg_6 12 49 p17/an07/sin2_2/int04_1 p39/dtti0x_0/adtg_2/tiob4_0/int06_0 13 48 p16/an06/sck0_1/int15_0 p3a/rto00_0/tioa0_1/int07_0/rtcco_2/subout_2/ic1_cin_0 14 47 p15/an05/ic1_cin_1/sot0_1/ic03_2/int14_0 p3b/rto01_0/tioa1_1/ic1_data_0 15 46 p14/an04/ic1_data_1/rts1_1/sin0_1/int03_1/ic02_2 p3c/rto02_0/tioa2_1/int18_2/ic1_rst_0 16 45 p13/an03/ic1_rst_1/sck1_1/rtcco_1/ic01_2/subout_1 p3d/rto03_0/tioa3_1/ic1_vpen_0 17 44 p12/an02/ic1_vpen_1/sot1_1/ic00_2 p3e/rto04_0/tioa4_1/int19_2/ic1_vcc_0/wkup8 18 43 p11/an01/ic1_vcc_1/sin1_1/int02_1/frck0_2/wkup1 p3f/rto05_0/tioa5_1/ic1_clk_0 19 42 p10/an00/ic1_clk_1/cts1_1 vss 20 41 vcc 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 p44/tioa4_0/int10_0/rts1_2/ic0_data_1 p45/lvdi/tioa5_0/ic0_cin_1 c vss vcc initx p46/x0a p47/x1a p48/vregctl p49/vwakeup vbat p4a/tiob0_0/scs70_1/int21_1 p4b/tiob1_0/sin7_1/int22_1/wkup7/igtrg0_0 p4c/tiob2_0/sot7_1/int12_0/cec0_0 p4d/tiob3_0/int13_0/sck7_1/wkup6 pe0/md1 md0 pe2/x0 pe3/x1 vss p0c/int19_0/udp0 vss p82/sck7_2 p81/sot7_2/int11_0 p80/sin7_2/int20_1 p60/sin5_0/mi2sdi5_0/tioa2_2/int15_1/wkup3/cec1_0/igtrg0_1 p61/sot5_0/mi2sdo5_0/tiob2_2/dtti0x_2 p62/sck5_0/mi2sck5_0/adtg_3/int07_1/tioa6_1/ic0_rst_0 p63/mi2sws5_0/int03_0/tiob6_1/ic0_data_0 p0f/nmix/crout_1/rtcco_0/subout_0/mi2smck5_0/wkup0/ic0_clk_0/sck4_0 p0e/cts4_0/tiob3_2/int21_0/ic0_vcc_0 p0d/rts4_0/tioa3_2/int20_0/ic0_vpen_0 p01/swclk p00/sot3_2/int14_1 p0b/int18_0/udm0 p0a/sin4_0/int00_2/wkup5/ic0_cin_0/uhconx0/cec0_1 p07/an22/adtg_0/sck4_2/int23_1/sot4_0 p04/sck3_2/int06_2 p03/swdio p02/sin3_2/tiob5_0 lqfp - 80 lqfp - 100
document number: 001 - 99224 rev.** page 10 of 115 s6e1b3 series preliminary fpt - 100p - m2 0 (top view) note: ? the number after the underscore ("_") in a pin name such as xxx_1 and xxx_2 indic ates the relocated port number. the channel on such pin has multiple functions, each of which has its own pin name. use the e xtended p ort f unction r egister (epfr) to select the pin to be used . 100 99 98 97 96 95 94 93 92 91 90 89 88 87 86 85 84 83 82 81 80 79 78 77 76 vcc 1 75 vss p50/int00_0/sin3_1 2 74 p20/an19/int05_0/crout_0 p51/int01_0/sot3_1 3 73 p21/an18/sin0_0/int06_1/wkup2 p52/int02_0/sck3_1 4 72 p22/an17/sot0_0/tiob7_1 p53/sin6_0/tioa1_2/int07_2 5 71 p23/an16/sck0_0/tioa7_1/rto00_1 p54/sot6_0/tiob1_2/int18_1 6 70 p1e/an14/rts4_1/adtg_5/frck0_1/int23_2 p55/sck6_0/adtg_1/int19_1 7 69 p1d/an13/cts4_1/dtti0x_1/int22_2 p56/int08_2/mi2smck6_1/wkup9/cec1_1 8 68 p1c/an12/sck4_1/ic03_1/int21_2 p30/tiob0_1/scs60_1/int03_2/mi2sws6_1/wkup4 9 67 p1b/an11/sot4_1/ic02_1/int20_2 p31/tiob1_1/sck6_1/mi2sck6_1/int04_2 10 66 p1a/an10/sin4_1/ic01_1/int05_1 p32/tiob2_1/sot6_1/mi2sdo6_1/int05_2 11 65 p19/an09/sck2_2/ic00_1 p33/int04_0/tiob3_1/sin6_1/mi2sdi6_1/adtg_6 12 64 p18/an08/sot2_2 p34/scs61_1/frck0_0/tiob4_1 13 63 avrh p35/scs62_1/ic03_0/tiob5_1/int08_1 14 62 avrl p36/ic02_0/sin5_2/int09_1/wkup11 15 61 avss p37/ic01_0/sot5_2/int10_1 16 60 avcc p38/ic00_0/sck5_2/int11_1 17 59 p17/an07/sin2_2/int04_1 p39/dtti0x_0/adtg_2/tiob4_0/int06_0 18 58 p16/an06/sck0_1/int15_0 p3a/rto00_0/tioa0_1/int07_0/rtcco_2/subout_2/ic1_cin_0 19 57 p15/an05/ic1_cin_1/sot0_1/ic03_2/int14_0 p3b/rto01_0/tioa1_1/ic1_data_0 20 56 p14/an04/ic1_data_1/rts1_1/sin0_1/int03_1/ic02_2 p3c/rto02_0/tioa2_1/int18_2/ic1_rst_0 21 55 p13/an03/ic1_rst_1/sck1_1/rtcco_1/ic01_2/subout_1 p3d/rto03_0/tioa3_1/ic1_vpen_0 22 54 p12/an02/ic1_vpen_1/sot1_1/ic00_2 p3e/rto04_0/tioa4_1/int19_2/ic1_vcc_0/wkup8 23 53 p11/an01/ic1_vcc_1/sin1_1/int02_1/frck0_2/wkup1 p3f/rto05_0/tioa5_1/ic1_clk_0 24 52 p10/an00/ic1_clk_1/cts1_1 vss 25 51 vcc 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 vcc p40/tioa0_0/int12_1/sin1_2/ic0_clk_1 p41/tioa1_0/int13_1/sot1_2/ic0_vcc_1 p42/tioa2_0/int08_0/sck1_2/ic0_vpen_1 p43/tioa3_0/int09_0/adtg_7/cts1_2/ic0_rst_1 p44/tioa4_0/int10_0/rts1_2/ic0_data_1 p45/lvdi/tioa5_0/ic0_cin_1 c vss vcc initx p46/x0a p47/x1a p48/vregctl p49/vwakeup vbat p4a/tiob0_0/scs70_1/int21_1 p4b/tiob1_0/sin7_1/int22_1/wkup7/igtrg0_0 p4c/tiob2_0/sot7_1/int12_0/cec0_0 p4d/tiob3_0/int13_0/sck7_1/wkup6 pe0/md1 md0 pe2/x0 pe3/x1 vss p61/sot5_0/mi2sdo5_0/tiob2_2/dtti0x_2 vss p82/sck7_2 p81/sot7_2/int11_0 p80/sin7_2/int20_1 p60/sin5_0/mi2sdi5_0/tioa2_2/int15_1/wkup3/cec1_0/igtrg0_1 p06/an21/tiob5_2/sot4_2/int01_1 p62/sck5_0/mi2sck5_0/adtg_3/int07_1/tioa6_1/ic0_rst_0 p63/mi2sws5_0/int03_0/tiob6_1/ic0_data_0 p0f/nmix/crout_1/rtcco_0/subout_0/mi2smck5_0/wkup0/ic0_clk_0/sck4_0 p0e/cts4_0/tiob3_2/int21_0/ic0_vcc_0 p0d/rts4_0/tioa3_2/int20_0/ic0_vpen_0 p0c/int19_0/udp0 p0b/int18_0/udm0 p0a/sin4_0/int00_2/wkup5/ic0_cin_0/uhconx0/cec0_1 p09/tiob0_2/rts4_2/int17_0 p08/an23/tioa0_2/cts4_2/int16_0 p07/an22/adtg_0/sck4_2/int23_1/sot4_0 vcc p05/an20/tioa5_2/sin4_2/int00_1/wkup10 p04/sck3_2/int06_2 p03/swdio p02/sin3_2/tiob5_0 p01/swclk p00/sot3_2/int14_1 lqfp - 100 lqfp - 100
document number: 001 - 99224 rev.** page 11 of 115 s6e1b3 series preliminary fpt - 120 p - m 21 (top view) note: ? the number after the underscore ("_") in a pin name such as xxx_1 and xxx_2 indic ates the relocated port number. the channel on such pin has multiple functions, each of which has its own pin name. use the e xtended p ort f unction r egister (epfr) to select the pin to be used . 120 119 118 117 116 115 114 113 112 111 110 109 108 107 106 105 104 103 102 101 100 99 98 97 96 95 94 93 92 91 vcc 1 90 vss p50/int00_0/sin3_1 2 89 p20/an19/int05_0/crout_0 p51/int01_0/sot3_1 3 88 p21/an18/sin0_0/int06_1/wkup2 p52/int02_0/sck3_1 4 87 p22/an17/sot0_0/tiob7_1 p53/sin6_0/tioa1_2/int07_2 5 86 p23/an16/sck0_0/tioa7_1/rto00_1 p54/sot6_0/tiob1_2/int18_1 6 85 p24/sin2_1/rto01_1/int17_1 p55/sck6_0/adtg_1/int19_1 7 84 p25/sot2_1/rto02_1 p56/sin1_0/int08_2/mi2smck6_1/wkup9/cec1_1 8 83 p26/sck2_1/rto03_1 p57/sot1_0 9 82 p27/an15/rto04_1/tioa6_2/int02_2 p58/sck1_0 10 81 p28/adtg_4/rto05_1/tiob6_2 p59/sin7_0/int16_1 11 80 p1e/an14/rts4_1/adtg_5/frck0_1/int23_2 p5a/sot7_0/int16_2 12 79 p1d/an13/cts4_1/dtti0x_1/int22_2 p5b/sck7_0/int17_2 13 78 p1c/an12/sck4_1/ic03_1/int21_2 p30/tiob0_1/scs60_1/int03_2/mi2sws6_1/wkup4 14 77 p1b/an11/sot4_1/ic02_1/int20_2 p31/tiob1_1/sck6_1/mi2sck6_1/int04_2 15 76 p1a/an10/sin4_1/ic01_1/int05_1 p32/tiob2_1/sot6_1/mi2sdo6_1/int05_2 16 75 p19/an09/sck2_2/ic00_1 p33/int04_0/tiob3_1/sin6_1/mi2sdi6_1/adtg_6 17 74 p18/an08/sot2_2 p34/scs61_1/frck0_0/tiob4_1 18 73 avrh p35/scs62_1/ic03_0/tiob5_1/int08_1 19 72 avrl p36/ic02_0/sin5_2/int09_1/wkup11 20 71 avss p37/ic01_0/sot5_2/int10_1 21 70 avcc p38/ic00_0/sck5_2/int11_1 22 69 p17/an07/sin2_2/int04_1 p39/dtti0x_0/adtg_2/tiob4_0/int06_0 23 68 p16/an06/sck0_1/int15_0 p3a/rto00_0/tioa0_1/int07_0/rtcco_2/subout_2/ic1_cin_0 24 67 p15/an05/ic1_cin_1/sot0_1/ic03_2/int14_0 p3b/rto01_0/tioa1_1/ic1_data_0 25 66 p14/an04/ic1_data_1/rts1_1/sin0_1/int03_1/ic02_2 p3c/rto02_0/tioa2_1/int18_2/ic1_rst_0 26 65 p13/an03/ic1_rst_1/sck1_1/rtcco_1/ic01_2/subout_1 p3d/rto03_0/tioa3_1/ic1_vpen_0 27 64 p12/an02/ic1_vpen_1/sot1_1/ic00_2 p3e/rto04_0/tioa4_1/int19_2/ic1_vcc_0/wkup8 28 63 p11/an01/ic1_vcc_1/sin1_1/int02_1/frck0_2/wkup1 p3f/rto05_0/tioa5_1/ic1_clk_0 29 62 p10/an00/ic1_clk_1/cts1_1 vss 30 61 vcc 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 vcc p40/tioa0_0/int12_1/sin1_2/ic0_clk_1 p41/tioa1_0/int13_1/sot1_2/ic0_vcc_1 p42/tioa2_0/int08_0/sck1_2/ic0_vpen_1 p43/tioa3_0/int09_0/adtg_7/cts1_2/ic0_rst_1 p44/tioa4_0/int10_0/rts1_2/ic0_data_1 p45/lvdi/tioa5_0/ic0_cin_1 c vss vcc initx p46/x0a p47/x1a p48/vregctl p49/vwakeup vbat p4a/tiob0_0/scs70_1/int21_1 p4b/tiob1_0/sin7_1/int22_1/wkup7/igtrg0_0 p4c/tiob2_0/sot7_1/int12_0/cec0_0 p4d/tiob3_0/int13_0/sck7_1/wkup6 p70/scs71_1/tioa4_2 p71/scs72_1/tiob4_2/int13_2 p72/sin2_0/tioa6_0/int14_2 p73/sot2_0/tiob6_0/int15_2 p74/sck2_0 pe0/md1 md0 pe2/x0 pe3/x1 vss p61/sot5_0/mi2sdo5_0/tiob2_2/dtti0x_2 vss p82/sck7_2 p81/sot7_2/int11_0 p80/sin7_2/int20_1 p60/sin5_0/mi2sdi5_0/tioa2_2/int15_1/wkup3/cec1_0/igtrg0_1 p0b/int18_0/udm0 p62/sck5_0/mi2sck5_0/adtg_3/int07_1/tioa6_1/ic0_rst_0 p63/sin5_1/mi2sws5_0/int03_0/tiob6_1/ic0_data_0 p64/sot5_1/tioa7_0/int10_2 p65/sck5_1/tiob7_0/int23_0 p66/sin3_0/int11_2 p67/sot3_0/tioa7_2/int22_0 p68/sck3_0/tiob7_2/int12_2 p0f/nmix/crout_1/rtcco_0/subout_0/mi2smck5_0/wkup0/ic0_clk_0/sck4_0 p0e/cts4_0/tiob3_2/int21_0/ic0_vcc_0 p0d/rts4_0/tioa3_2/int20_0/ic0_vpen_0 p0c/int19_0/udp0 vcc p0a/sin4_0/int00_2/wkup5/ic0_cin_0/uhconx0/cec0_1 p09/tiob0_2/rts4_2/int17_0 p08/an23/tioa0_2/cts4_2/int16_0 p07/an22/adtg_0/sck4_2/int23_1/sot4_0 p06/an21/tiob5_2/sot4_2/int01_1 p05/an20/tioa5_2/sin4_2/int00_1/wkup10 p04/sck3_2/int06_2 p03/swdio p02/sin3_2/tiob5_0 p01/swclk p00/sot3_2/int14_1 lqfp - 120
document number: 001 - 99224 rev.** page 12 of 115 s6e1b3 series preliminary 4. list of pin functions list of pin num bers the number after the underscore ("_") in a pin name such as xxx_1 and xxx_2 indic ates the relocated port number. the channel on such pin has multiple functions, each of which has its own pin name. use the e xtended p ort f unction r egister (epfr) to select the pin to be used . pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 1 1 1 v cc - 2 2 2 p50 i j sin3_1 int00_0 3 3 3 p51 i j sot3_1 int01_0 4 4 4 p52 i j sck3_1 int02_0 5 5 5 p 53 i j sin6_0 tioa1_2 int07_2 6 6 6 p54 i j sot6_0 tiob1_2 int18_1 7 7 7 p55 i j sck6_0 adtg_1 int19_1 8 8 8 p56 i o mi2smck6_1 cec1_1 int08_2 wkup9 - - sin1_0 9 - - p57 f i sot1_0 10 - - p58 f i sck1_0 11 - - p59 f j sin7_0 int16_1 12 - - p5a f j sot7_0 int16_2
document number: 001 - 99224 rev.** page 13 of 115 s6e1b3 series preliminary pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 13 - - p5b f j sck7_0 int17_2 14 9 9 p30 i n tiob0_1 scs60_1 mi2sws 6_1 int03_2 wkup4 15 10 10 p31 i j tiob1_1 sck6_1 mi2sck 6_1 int04_2 16 11 11 p32 i j tiob2_1 sot6_1 mi2sdo 6_1 int05_2 17 12 12 p33 i j tiob3_1 sin6_1 mi2sdi 6_1 int04_0 adtg_6 18 13 - p34 i i scs6 1 _1 frck0_0 tiob4_1 19 14 - p35 i j scs62_1 ic03_0 tiob5_1 int08_1 20 15 - p36 i n ic02_0 sin5_2 int09_1 wkup11 21 16 - p37 i j ic01_0 sot5_2 int10_1 22 17 - p38 f j ic00_0 sck5_2 int11_1
document number: 001 - 99224 rev.** page 14 of 115 s6e1b3 series preliminary pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 23 18 13 p39 i j dtti0x_0 tiob4_0 adtg_2 int06_0 24 19 14 p3a i j rto00_0 tioa0_1 rtcco_2 subout_2 ic1_cin_0 int07_0 25 20 15 p3b i i rto01_0 tioa1_1 ic1_data_0 26 21 16 p3c i j rto02_0 tioa2_1 int18_2 ic1_rst_0 27 22 17 p3d i i rto03_0 tioa3_1 ic1_vpen_0 28 23 18 p3e i n rto04_0 tioa4_1 ic1_vcc_0 int19_2 wkup8 29 24 19 p3f i i rto05_0 tioa5_1 ic1_clk_0 30 25 20 vss - - 31 26 - vcc - - 32 27 - p40 f j tioa0_0 ic0_clk_1 int12_1 sin1_2 33 28 - p41 f j tioa1_0 sot1_2 ic0_vcc_1 int13_1
document number: 001 - 99224 rev.** page 15 of 115 s6e1b3 series preliminary pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 34 29 - p42 f j tioa2_0 sck1_2 ic0_vpen_1 int08_0 35 30 - p43 f j tioa3_0 cts1_2 adtg_7 ic0_rst_1 int09_0 36 31 21 p44 i j tioa4_0 ic0_data_1 int10_0 rts1_2 37 32 22 p45 i i tioa5_0 ic0_cin_1 lvdi 38 33 23 c - - 39 34 24 vss - - 40 35 25 vcc - - 41 36 26 initx b c 42 37 27 p46 d e x0a 43 38 28 p47 e f x1a 44 39 29 p48 i i v regctl 45 40 30 p49 i i vwakeup 46 41 31 vbat - - 47 42 32 p4a i j tiob0_0 scs70_1 int21_1 48 43 33 p4b i n tiob1_0 sin7_1 int22_1 wkup7 igtrg0_0 49 44 34 p4c i r tiob2_0 sot7_1 cec0_0 int12_0 50 45 35 p4d i n tiob3_0 sck7_1 int13_0 wkup6
document number: 001 - 99224 rev.** page 1 6 of 115 s6e1b3 series preliminary pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 51 - - p70 f i tioa4_2 scs71_1 52 - - p71 f j tiob4_2 scs72_1 int13_2 53 - - p72 f j sin2_0 tioa6_0 int14_2 54 - - p73 f j sot2_0 tiob6_0 int15_2 55 - - p74 f i sck2_0 56 46 36 pe0 c d md1 57 47 37 md0 j m 58 48 38 pe2 a a x0 59 49 39 pe3 a b x1 60 50 40 vss - - 61 51 41 vcc - - 62 52 42 p10 h k ic1_clk_1 cts1_1 an00 63 53 43 p11 h p ic1_vcc_1 sin1_1 frck0_2 int02_1 wkup1 an01 64 54 44 p12 h k ic1_vpen_1 sot1_1 ic00_2 an02 65 55 45 p13 h k ic1_rst_1 sck1_1 rtcco_1 ic01_2 subout_1 an03
document number: 001 - 99224 rev.** page 17 of 115 s6e1b3 series preliminary pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 66 56 46 p14 h l ic1_data_1 rts1_1 sin0_1 ic02_2 int03_1 an04 67 57 47 p15 h l ic1_cin_1 sot0_1 ic03_2 int14_0 an05 68 58 48 p16 h l sck0_1 int15_0 an06 69 59 49 p17 h l sin2_2 int04_1 an07 70 60 50 avcc - - 71 61 51 avss - - 72 62 52 avrl - - 73 63 53 avrh - - 74 64 54 p18 h k sot2_2 an08 75 65 55 p19 h k sck2_2 ic00_1 an09 76 66 56 p1a h l sin4_1 ic01_1 int05_1 an10 77 67 57 p1b h l sot4_1 ic02_1 int20_2 an11 78 68 - p1c h l sck4_1 ic03_1 int21_2 an12 79 69 - p1d h l cts4_1 dtti0x_1 int22_2 an13
document number: 001 - 99224 rev.** page 18 of 115 s6e1b3 series preliminary pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 80 70 - p1e h l rts4_1 frck0_1 adtg_5 int23_2 an14 81 - - p28 f i rto05_1 tiob6_2 adtg_ 4 82 - - p27 g l rto04_1 tioa6_2 int02_2 an15 83 - - p26 f i sck2_1 rto03_1 84 - - p25 f i sot2_1 rto02_1 85 - - p24 f j sin2_1 rto01_1 int17_1 86 71 58 p23 h k sck0_0 tioa7_1 rto00_1 an16 87 72 59 p22 h k sot0_0 tiob7_1 an17 88 73 60 p21 h p sin0_0 int06_1 wkup2 an18
document number: 001 - 99224 rev.** page 19 of 115 s6e1b3 series preliminary pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 89 74 - p20 h l int05_0 crout_0 an19 90 75 - vss - - 91 76 - vcc - - 92 77 61 p00 i j sot3_2 int14_1 93 78 62 p01 i h swclk 94 79 63 p02 i i sin3_2 tiob5_0 95 80 64 p03 i h swdio 96 81 65 p04 i j sck3_2 int06_2 97 82 - p05 h p tioa5_2 sin4_2 int00_1 wkup10 an20 98 83 - p06 h l tiob5_2 sot4_2 int01_1 an21 99 84 66 p07 h l sck4_2 adtg_0 int23_1 an22 sot4_0 100 85 - p08 h l tioa0_2 cts4_2 int16_0 an23 101 86 - p09 i j tiob0_2 rts4_2 int17_0
document number: 001 - 99224 rev.** page 20 of 115 s6e1b3 series preliminary pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 102 87 67 p0a i o sin4_0 int00_2 wkup5 ic0_cin_0 uhconx0 cec0_1 103 88 68 p0b k q int18_0 udm0 104 89 69 p0c k q int19_0 udp0 105 90 70 p0d i j rts4_0 tioa3_2 int20_0 ic0_vpen_0 106 91 71 p0e i j cts4_0 tiob3_2 int21_0 ic0_vcc_0 107 92 72 p0f i g crout_1 rtcco_0 subout_0 mi2smck5_0 nmix wkup0 ic0 _ clk_0 sck4_0 108 - - p68 f j sck3_0 tiob7_2 int12_2 109 - - p67 f j sot3_0 tioa7_2 int22_0 110 - - p66 f j sin3_0 int11_2 111 - - p65 f j sck5_1 tiob7_0 int23_0
document number: 001 - 99224 rev.** page 21 of 115 s6e1b3 series preliminary pin no . pin name i/o circuit type pin state type l qfp - 120 lqfp - 100 l qfp - 80 112 - - p64 f j sot5_1 tioa7_0 int10_2 113 93 73 p63 i j mi2sws5_0 int03_0 tiob6_1 ic0_data_0 - - sin5_1 114 94 74 p62 i j sck5_0 mi2sck 5_0 adtg_3 int07_1 tioa6_1 ic0_rst_0 115 95 75 p61 i i sot5_0 mi2sdo 5_0 tiob2_2 dtti0x_2 116 96 76 p60 i o sin5_0 mi2sdi5_0 tioa2_2 cec1_0 int15_1 wkup3 igtrg0_1 117 97 77 p80 i j sin7_2 int20_1 c0 118 98 78 p81 i j sot7_2 int11_0 c1 119 99 79 p82 i i sck7_2 120 100 80 vss - - * : 5 v tolerant i/o
document number: 001 - 99224 rev.** page 22 of 115 s6e1b3 series preliminary list of pin functions the number after the underscore ("_") in a pin name such as xxx_1 and xxx_2 indic ates the relocated port number. the channel on such pin has multiple functions, each of which has its own pin name. use the e xtended p ort f unction r egister (epfr) to select the pin to be used . pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 adc adtg_ 0 a/d converter external trigger input pin 99 84 66 adtg_ 1 7 7 7 adtg_2 23 18 13 adtg_3 114 94 74 adtg_4 81 - - adtg_5 80 70 - adtg_6 17 12 12 adtg_7 35 30 - an00 a/d converter analog input pin. anxx describes adc ch.xx. 62 52 42 an01 63 53 43 an02 64 54 44 an03 65 55 45 an04 66 56 46 an05 67 57 47 an06 68 58 48 an07 69 59 49 an08 74 64 54 an09 75 65 55 an10 76 66 56 an11 77 67 57 an12 78 68 - an13 79 69 - an14 80 70 - an15 82 - - an16 86 71 58 an17 87 72 59 an18 88 73 60 an19 89 74 - an20 97 82 - an21 98 83 - an22 99 84 66 an23 100 85 - base timer 0 tioa0_0 base timer ch . 0 tioa pin 32 27 - tioa0_1 24 19 14 tioa0_2 100 85 - tiob0_0 base timer ch.0 tiob pin 47 42 32 tiob0_1 14 9 9 tiob0_2 101 86 -
document number: 001 - 99224 rev.** page 23 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 base timer 1 tioa1_0 base timer ch.1 tioa pin 33 28 - tioa1_1 25 20 15 tioa1_2 5 5 5 tiob1_0 base timer ch.1 tiob pin 48 43 33 tiob1_1 15 10 10 tiob1_2 6 6 6 base timer 2 tioa2_0 base timer ch.2 tioa pin 34 29 - tioa2_1 26 21 16 tioa2_2 116 96 76 tiob2_0 base timer ch.2 tiob pin 49 44 34 tiob2_ 1 16 11 11 tiob2_2 115 95 75 base timer 3 tioa3_ 0 base timer ch.3 tioa pin 35 30 - tioa3_1 27 22 17 tioa3_2 105 90 70 tiob3_0 base timer ch.3 tiob pin 50 45 35 tiob3_1 17 12 12 tiob3_2 106 91 71 base timer 4 tioa4_0 base timer ch.4 tioa pin 36 31 21 tioa4_1 28 23 18 tioa4_2 51 - - tiob4_0 base timer ch.4 tiob pin 23 18 13 tiob4_1 18 13 - tiob4_2 52 - - base timer 5 tioa5_0 base timer ch.5 tioa pin 37 32 22 tioa5_1 29 24 19 tioa5_2 97 82 - tiob5_0 base timer ch.5 tiob pin 94 79 63 tiob5_1 19 14 - tiob5_2 98 83 - base timer 6 tioa6_0 base timer ch.6 tioa pin 53 - - tioa6_1 114 94 74 tioa6_2 82 - - tiob6_0 base timer ch.6 tiob pin 54 - - tiob6_1 113 93 73 tiob6_2 81 - - base timer 7 tioa7_0 base timer ch.7 tioa pin 112 - - tioa7_1 86 71 58 tioa7_2 109 - - tiob7_0 base timer ch.7 tiob pin 111 - - tiob7_1 87 72 59 tiob7_2 108 - - debugger swclk serial wire debug interface clock input pin 93 78 62 swdio serial wire debug interface data input / output pin 95 80 64
document number: 001 - 99224 rev.** page 24 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 external interrupt int00_0 external interrupt request 00 input pin 2 2 2 int00_1 97 82 - int00_2 102 87 67 int01_0 external interrupt request 01 input pin 3 3 3 int01_1 98 83 - int02_0 external interrupt request 02 input pin 4 4 4 int02_1 63 53 43 int02_ 2 82 - - int03_0 external interrupt request 03 input pin 113 93 73 int03_1 66 56 46 int03_2 14 9 9 int04_0 external interrupt request 04 input pin 17 12 12 int04_1 69 59 49 int04_ 2 15 10 10 int05_0 external interrupt request 05 input pin 89 74 - int05_1 76 66 56 int05_ 2 16 11 11 int06_0 external interrupt request 06 input pin 23 18 13 int06_1 88 73 60 int06_ 2 96 81 65 int07 _0 external interrupt request 07 input pin 24 19 14 int07 _1 114 94 74 int07 _ 2 5 5 5 int08 _0 external interrupt request 08 input pin 34 29 - int08 _1 19 14 - int08 _ 2 8 8 8 int09 _0 external interrupt request 09 input pin 35 30 - int09 _1 20 15 - int10 _0 external interrupt request 10 input pin 36 31 21 int10 _1 21 16 - int10 _ 2 112 - - int11 _0 external interrupt request 11 input pin 118 98 78 int11 _1 22 17 - int11 _ 2 110 - - int12 _0 external interrupt request 12 input pin 49 44 34 int12 _1 32 27 - int12 _ 2 108 - - int13 _0 external interrupt request 13 input pin 50 45 35 int13 _1 33 28 - int13 _ 2 52 - - int14 _0 external interrupt request 14 input pin 67 57 47 int14 _1 92 77 61 int14 _ 2 53 - -
document number: 001 - 99224 rev.** page 25 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 external interrupt int15_ 0 external interrupt request 15 input pin 68 58 48 int15_1 116 96 76 int15_ 2 54 - - int16 _ 0 external interrupt request 16 input pin 100 85 - int16 _1 11 - - int16 _ 2 12 - - int17 _ 0 external interrupt request 17 input pin 101 86 - int17 _1 85 - - int17 _ 2 13 - - int18 _ 0 external interrupt request 18 input pin 103 88 68 int18 _1 6 6 6 int18 _ 2 26 21 16 int19 _ 0 external interrupt request 19 input pin 104 89 69 int19 _1 7 7 7 int19 _ 2 28 23 18 int20 _ 0 external interrupt request 20 input pin 105 90 70 int20 _1 117 97 77 int20 _ 2 77 67 57 int21 _ 0 external interrupt request 21 input pin 106 91 71 int21 _1 47 42 32 int21 _ 2 78 68 - int22 _ 0 external interrupt request 22 input pin 109 - - int22 _1 48 43 33 int22 _ 2 79 69 - int23 _ 0 external interrupt request 23 input pin 111 - - int23 _1 99 84 66 int23 _ 2 80 70 - nmix non - maskable interrupt input pin 107 92 72 gpio p00 general - purpose i/o port 0 92 77 61 p01 93 78 62 p02 94 79 63 p03 95 80 64 p04 96 81 65 p05 97 82 - p06 98 83 - p07 99 84 66 p08 100 85 - p09 101 86 - p0a 102 87 67 p0b 103 88 68 p0c 104 89 69 p0d 105 90 70 p0e 106 91 71 p0f 107 92 72
document number: 001 - 99224 rev.** page 26 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 gpio p10 general - purpose i/o port 1 62 52 42 p11 63 53 43 p12 64 54 44 p13 65 55 45 p14 66 56 46 p15 67 57 47 p16 68 58 48 p17 69 59 49 p18 74 64 54 p19 75 65 55 p1a 76 66 56 p1b 77 67 57 p1c 78 68 - p1d 79 69 - p1e 80 70 - p2 0 general - purpose i/o port 2 89 74 - p21 88 73 60 p22 87 72 59 p23 86 71 58 p24 85 - - p25 84 - - p26 83 - - p27 82 - - p28 81 - - p3 0 general - purpose i/o port 3 14 9 9 p31 15 10 10 p32 16 11 11 p33 17 12 12 p34 18 13 - p35 19 14 - p36 20 15 - p37 21 16 - p38 22 17 - p39 23 18 13 p3a 24 19 14 p3b 25 20 15 p3c 26 21 16 p3d 27 22 17 p3e 28 23 18 p3f 29 24 19
document number: 001 - 99224 rev.** page 27 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 gpio p40 general - purpose i/o port 4 32 27 - p41 33 28 - p42 34 29 - p43 35 30 - p44 36 31 21 p45 37 32 22 p46 42 37 27 p47 43 38 28 p48 44 39 29 p49 45 40 30 p4a 47 42 32 p4b 48 43 33 p4c 49 44 34 p4d 50 45 35 p50 general - purpose i/o port 5 2 2 2 p51 3 3 3 p52 4 4 4 p53 5 5 5 p54 6 6 6 p55 7 7 7 p56 8 8 8 p57 9 - - p58 10 - - p59 11 - - p5a 12 - - p5b 13 - - p60 general - purpose i/o port 6 116 96 76 p61 115 95 75 p62 114 94 74 p63 113 93 73 p64 112 - - p65 111 - - p66 110 - - p67 109 - - p68 108 - - p 7 0 general - purpose i/o port 7 51 - - p71 52 - - p72 53 - - p73 54 - - p74 55 - - p80 general - purpose i/o port 8 117 97 77 p81 118 98 78 p82 119 99 79 pe0 * general - purpose i/o port e 56 46 36 pe2 58 48 38 pe3 59 49 39
document number: 001 - 99224 rev.** page 28 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 multi - function serial 0 sin0_0 multi - function serial interface ch.0 input pin 88 73 60 sin0_1 66 56 46 sot0_0 (sda0_0) multi - function serial interface ch.0 output pin. this pin operates as sot0 when used as a uart/csio/lin pin (operation mode 0 to 3) and as sda0 when used as an i 2 c pin (operation mode 4). 87 72 59 sot0_1 (sda0_1) 67 57 47 sck0_0 (scl0_0) multi - function serial interface ch.0 clock i/o pin. this pin operates as sck0 when used as a csio pin (operation mode 2) and as scl0 when u sed as an i 2 c pin (operation mode 4). 86 71 58 sck0_ 1 (scl0_ 1 ) 68 58 48 multi - function serial 1 sin1_ 0 multi - function serial interface ch.1 input pin 8 - - sin1_1 63 53 43 sin1_ 2 32 27 - sot1_ 0 (sda1_0) multi - function serial interface ch. 1 output pin. this pin operates as sot 1 when used as a uart/csio/lin pin (operation mode 0 to 3) and as sda 1 when used as an i 2 c pin (operation mode 4). 9 - - sot1_1 (sda1_1) 64 54 44 sot1_ 2 (sda1_ 2 ) 33 28 - sck1_ 0 (scl1_0) multi - function serial interface ch.1 clock i/o pin . this pin operates as sck1 when used as a csio pin (operation mode 2) and as scl1 when used as an i 2 c pin (operation mode 4). 10 - - sck1_1 (scl1_1) 65 55 45 sck1_ 2 (scl1_ 2 ) 34 29 - multi - function serial 2 sin2_0 mult i - function serial interface ch.2 input pin 53 - - sin2_1 85 - - sin2_2 69 59 49 sot2 _ 0 (sda2_0) multi - function serial interface ch. 2 output pin. this pin operates as sot2 when used as a uart/csio/lin pin (op eration mode 0 to 3) and as sda2 when used as an i 2 c pin (operation mode 4). 54 - - sot2 _ 1 (sda2_1) 84 - - sot2 _ 2 (sda2_2) 74 64 54 sck2 _ 0 (scl2_0) multi - function serial interface ch.1 clock i/o pin . this pin operates as sck2 when used as a csio pin (operation mode 2) and as scl2 when used as an i 2 c pin (operation mode 4). 55 - - sck2 _ 1 (scl2_1) 83 - - sck2 _ 2 (scl2_2) 75 65 55
document number: 001 - 99224 rev.** page 29 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 multi - function serial 3 sin3_0 multi - functi on serial interface ch.3 input pin 110 - - sin3_1 2 2 2 sin3_ 2 94 79 63 sot3_0 (sda3_ 0 ) multi - function serial interface ch.3 output pin. this pin operates as sot3 when used as a uart/csio/lin pin (operation mode 0 to 3) and as sda3 when used as an i 2 c pin (operation mode 4). 109 - - sot3_ 1 (sda3_1) 3 3 3 sot3_ 2 (sda3_ 2 ) 92 77 61 sck3_ 0 (scl3_ 0 ) multi - function serial interface ch.3 clock i/o pin. this pin operates as sck3 when used as a csio (operation mode 2) and as scl3 when used as an i 2 c pin (operation mode 4). 108 - - sck3_ 1 (scl3_ 1 ) 4 4 4 sck3_ 2 (scl3_ 2 ) 96 81 65 multi - function serial 4 sin4 _0 multi - functi on serial interface ch.4 input pin 102 87 67 sin4 _1 76 66 56 sin4 _ 2 97 82 - sot4 _0 (sda4 _ 0 ) mult i - function serial interface ch.4 output pin. this pin operates as sot4 when used as a uart/csio/lin pin (operation mode 0 to 3) and as sda4 when used as an i 2 c pin (operation mode 4). 99 84 66 sot4 _ 1 (sda4 _1) 77 67 57 sot4 _ 2 (sda4 _ 2 ) 98 83 - sck4 _ 0 (scl4 _ 0 ) mult i - function serial interface ch.4 clock i/o pin. this pin operates as sck4 when used as a csio (operation mode 2) and as s cl4 when used as an i 2 c pin (operation mode 4). 107 92 72 sck4 _ 1 (scl 4 _ 1 ) 78 68 - sck4 _ 2 (scl4 _ 2 ) 99 84 66 cts4_0 multi - function serial interface ch4 cts input pin 106 91 71 cts4_1 79 69 - cts4_2 100 85 - rts4_0 multi - function serial interface ch4 rts input pin 105 90 70 rts4_1 80 70 - rts4_2 101 86 -
document number: 001 - 99224 rev.** page 30 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 multi - function serial 5 sin5 _0 ( mi2sdi 5_0) multi - functi on serial interface ch.5 input pin . sin5_0 pin operates as i2sin5_0 when used as an i 2 s pin (operation mode 2 ). 116 96 76 sin5 _1 113 - - sin5 _ 2 20 15 - sot5 _0 (sda5 _ 0 ) ( mi2sdo 5_0) mult i - function serial interface ch.5 output pin. this pin operates as sot5 when used as a uart/csio/lin pin (operation mode 0 to 3) and as sda5 when used as an i 2 c pin (operation mode 4). sot5_0 pin operates as mi2sdo 5_0 when used as an i 2 s pin (operation mode 2 ). 115 95 75 sot5 _ 1 (sda5 _1) 112 - - sot5 _ 2 (sda5 _ 2 ) 21 16 - sck5 _ 0 (scl5 _ 0 ) ( mi2sck 5_0) mult i - function serial interface ch.5 clock i/o pin. this pin operates as sck5 when used as a csio (operation mode 2) and as s cl5 when used as an i 2 c pin (operation mode 4). sck5_0 pin operates as mi2sck 5_0 when used as an i 2 s pin (operation mode 2 ). 114 94 74 sck5 _ 1 (scl 5 _ 1 ) 111 - - sck5 _ 2 (scl5 _ 2 ) 22 17 - mi2sws 5_0 i 2 s word select (ws) output 113 93 73 multi - function serial 6 sin6 _0 multi - functi on serial interface ch.6 input pin . sin6_1 pin operates as i2sin6_1 when used as an i 2 s pin (operation mode 2 ). 5 5 5 sin6 _1 ( mi2sdi 6_1) 17 12 12 sot6 _0 (sda6 _ 0 ) mult i - function serial interface ch.6 output pin. this pin operates as sot6 when used as a uart/csio/lin pin (operation mode 0 to 3) and as sda6 when used as an i 2 c pin (operation mode 4). sot6_1 pin operates as mi2sdo 6_1 when used as an i 2 s pin (operation mode 2 ). 6 6 6 sot6 _ 1 (sda6 _1) ( mi2sdo 6_1) 16 11 11 sck6 _ 0 (scl6 _ 0 ) mult i - function serial interface ch.6 clock i/o pin. this pin operates as sck6 when used as a csio (operation mode 2) and as s cl6 when used as an i 2 c pin (operation mode 4). sck6_6 pin operates as mi2sck 6_1 when used as an i 2 s pin (operation mode 2 ). 7 7 7 sck6 _ 1 (scl 6 _ 1 ) ( mi2sck 6_1) 15 10 10 scs6 0_ 1 multi - function serial interface ch. 6 serial chip select 0 input/output pin . 14 9 9 scs6 1 _ 1 multi - function serial interface ch. 6 serial chip select 1 input/output pin . 18 13 - scs6 2 _ 1 multi - function serial interface ch. 6 serial chip select 2 input/output pin . 19 14 - mi2sws 6_1 i 2 s word select (ws) output 14 9 9
document number: 001 - 99224 rev.** page 31 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 multi - function serial 7 sin7 _0 multi - functi on serial interface ch.7 input pin 11 - - sin7 _1 48 43 33 sin7 _ 2 117 97 77 sot7 _0 (sda7 _ 0 ) mult i - function serial interface ch.7 output pin. this pin operates as sot7 when used as a uart/csio/lin pin (operation mode 0 to 3) and as sda7 when used as an i 2 c pin (operation mode 4). 12 - - sot7 _ 1 (sda7 _1) 49 44 34 sot7 _ 2 (sda7 _ 2 ) 118 98 78 sck7 _ 0 (scl7 _ 0 ) mult i - function serial interface ch.7 clock i/o pin. this pin operates as sck7 when used as a csio (operation mode 2) and as s cl7 when used as an i 2 c pin (operation mode 4). 13 - - sck7 _ 1 (scl 7 _ 1 ) 50 45 35 sck7 _ 2 (scl7 _ 2 ) 119 99 79 scs7 0_ 1 multi - function serial interface ch. 7 serial chip select 0 input/output pin . 47 42 32 scs7 1 _ 1 multi - function serial interface ch. 7 serial chip select 1 input/output pin . 51 - - scs7 2 _ 1 multi - function serial interface ch. 7 serial chip select 2 input/output pin . 52 - - smart card interface 0 ic0_vcc_0 smart card ch.0 power enable output pin 106 91 71 ic0_vcc_1 33 28 - ic0_vpen_0 smart card ch.0 programming output pin 105 90 70 ic0_vpen_1 34 29 - ic0_rst_0 smart card ch.0 reset output pin 114 94 74 ic0_rst_1 35 30 - ic0_cin_0 smart card ch.0 insert detection input pin 102 87 67 ic0_cin_1 37 32 22 ic0_clk_0 smart card ch.0 serial interface clock output pin 107 92 72 ic0_clk_1 32 27 - ic0_data_0 smart card ch.0 serial interface data input/output pin 113 93 73 ic0_data_1 36 31 21 smart card interface 1 ic1_vcc_0 smart card ch.1 power enable output pin 28 23 18 ic1_vcc_1 63 53 43 ic1_vpen_0 smart card ch.1 programming output pin 27 22 17 ic1_vpen_1 64 54 44 ic1_rst_0 smart card ch.1 reset output pin 26 21 16 ic1_rst_1 65 55 45 ic1_cin_0 smart card ch.1 insert detection input pin 24 19 14 ic1_cin_1 67 57 47 ic1_clk_0 smart card ch.1 serial interface clock output pin 29 24 19 ic1_clk_1 62 52 42 ic1_data_0 smart card ch.1 serial interface data input/output pin 25 20 15 ic1_data_1 66 56 46 usb udm0 usb device /host d C pin 103 88 68 udp0 usb device /host d + pin 104 89 69 uhconx 0 usb external pull - up control pin 102 87 67
document number: 001 - 99224 rev.** page 32 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 multi - function timer 0 dtti0x_ 0 input signal of waveform generator control ling rto00 to rto05 outputs of multi - function t imer 0. 23 18 13 dtti0x_ 1 79 69 - dtti0x_ 2 115 95 75 frck0_0 16 - bit free - run timer ch.0 external clock input pin . 18 13 - frck0_ 1 80 70 - frck0_2 63 53 43 ic00_0 16 - bit input capture input pin of multi - function timer 0. icxx describes channel number. 22 17 - ic00_1 75 65 55 ic00_2 64 54 44 ic01_0 21 16 - ic01_ 1 76 66 56 ic01_2 65 55 45 ic02_0 20 15 - ic02_ 1 77 67 57 ic02_2 66 56 46 ic03_0 19 14 - ic03_ 1 78 68 - ic03_2 67 57 47 rto00_0 (ppg00_0) waveform generator output pin of multi - function timer 0. this pin operates as ppg00 when it is used in ppg0 output mode. 24 19 14 rto00_1 (ppg00_1) 86 71 58 rto01_0 (ppg0 0 _0) waveform generator output pin of multi - function timer 0. this pin operates as ppg0 0 when it is used in ppg0 output mode. 25 20 15 rto01_1 (ppg00_1) 85 - - rto02_0 (ppg02_0) waveform generator output pin of multi - function timer 0. this pin operates as ppg02 when it is used in ppg0 output mode. 26 21 16 rto02_1 (ppg02_1) 84 - - rto03_0 (ppg0 2 _0) waveform generator output pin of multi - function timer 0. this pin operates as ppg0 2 when it is used in ppg0 output mode. 27 22 17 rto03_1 (ppg02_1) 83 - - rto04_0 (ppg04_0) waveform generator output pin of multi - function timer 0. this pin operates as ppg04 when it is used in ppg0 output mode. 28 23 18 rto04_1 (ppg04_1) 82 - - rto05_0 (ppg04_0) waveform generator output pin of multi - function timer 0. this pin operates as ppg04 when it is used in ppg0 output mode. 29 24 19 rto05_1 (ppg04_1) 81 - - igtrg0_ 0 ppg igbt mode external trigger input pin 48 4 3 3 3 igtrg0_1 116 96 76
document number: 001 - 99224 rev.** page 33 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 real - time clock rtcco_0 0.5 - seconds pulse output pin of real - time clock 107 9 2 72 rtcco_1 65 55 45 rtcco_2 24 19 1 4 subout_0 sub clock output pin 107 9 2 72 subout_1 65 55 45 subout_2 24 19 1 4 hdmi - cec/ remote control reception cec0_0 hdmi - cec/remote control reception ch.0 input/output pin 49 44 34 cec0_1 102 87 67 cec1_0 hdmi - cec/remote control reception ch.1 input/output pin 116 96 76 cec1_1 8 8 8 low - power consumption mode wkup0 deep standby mode return signal input pin 107 92 72 wkup1 63 53 43 wkup2 88 73 60 wkup3 116 96 76 wkup 4 14 9 9 wkup 5 102 87 67 wkup 6 50 45 35 wkup 7 48 43 33 wkup 8 28 23 18 wkup 9 8 8 8 wkup 10 97 82 - wkup 11 20 15 - vbat lvdi input pin to mo nitor the external voltage . 37 32 22 vwakeup the return signal input pin from a hibernation state 45 40 30 v regctl on - board regulator control pin 44 39 29 reset initx external reset input pin. a reset is valid when initx="l". 41 36 26 mode md0 mode 0 pin. during normal operation, input md0="l". during serial programming to flash memory, input md0="h " . 57 47 37 md1 mode 1 pin. during normal operation, input is not needed. during serial programming to flash memory, md1 = "l" must be input. 56 46 36 power vcc power supply p in 1 1 1 31 26 - 40 35 25 61 51 41 91 76 - vbat power vbat vbat power supply pin backup power supply (battery etc.) and system power supply 46 41 31
document number: 001 - 99224 rev.** page 34 of 115 s6e1b3 series preliminary pin function pin name function description pin no . lqfp - 120 lqfp - 100 lqfp - 80 gnd vss gnd pin 30 25 20 39 34 24 60 50 40 90 75 - 120 100 80 clock x0 main clock (oscillation) input pin 58 48 38 x0a sub clock (oscillation) input pin 42 37 27 x1 main clock (oscillation) i/o pin 59 49 39 x1a sub clock (oscillation) i/o pin 43 38 28 crout_ 0 built - in high - speed c r oscillation clock output port 89 74 - crout_1 built - in high - speed c r oscillation clock output port 107 92 72 analog power avcc a/d converter analog power supply pin 70 60 50 avrh a/d converter analog reference voltage input pin 73 63 53 analog gnd av ss a/d converter analog reference voltage input pin 71 61 51 c pin c power supply stabilization capacitance pin 38 33 23 * : pe0 is an open drain pin, cannot output high.
document number: 001 - 99224 rev.** page 35 of 115 s6e1b3 series preliminary 5. i /o circuit type type circuit remarks a it is possible to select the main oscillation / gpio function when the main oscillation is selected. oscillation feedback resistor : approximately 1 m with standby mode control when the gpio is selected. cmos level output. cmos level hysteresis input with pull - up resistor control with standby mode control pull - up resistor : approximately 33 k i oh = - 4ma, i ol = 4 ma p - ch p - ch n - ch r r p - ch p - ch n - ch x0 x1 pull - up resistor feedback resistor pull - up resistor pull - up resistor control digital output digital output pull - up resistor control digital input standby mode control clock input standby mode control digital input standby mode control digital output digital output
document number: 001 - 99224 rev.** page 36 of 115 s6e1b3 series preliminary type circuit remarks b cmos level hysteresis input pull - up resistor : approximately 33 k c open drain output cmos level hysteresis input d ? cmos level output ? please refer to the " vbat domain" setting of io in of the peripheral manual main part (mn710 - 00001) " . e it is possible to select the sub oscillation / gpio function when the sub oscillation is selected. ? oscillation feedback resistor : approximately 12 m when the gpio is selected. ? cmos level hysteresis input ? please refer to the " vbat domain" setting of io in the peripheral manual main part (mn710 - 00001) " . pull - up resistor digital in put digital input digital out put digital input sub osc/gpio select osc x0a digital input sub osc/ gpio select osc sub osc enable clock input x 1 a r r r x n-ch
document number: 001 - 99224 rev.** page 37 of 115 s6e1b3 series preliminary type circuit remarks f ? cmos level output ? cmos level hysteresis input ? with pull - up resistor control ? with standby mode control ? pull - up resistor : approximately 33 k ? i oh = - 4 ma, i ol = 4 ma ? when this pin is used as an i 2 c pin, the digital output p - ch transistor is always off g ? cmos level output ? cmos level hysteresis input ? with input control ? analog input ? with pull - up resistor control ? with standby mode control ? pull - up resistor : approximately 33 k ? i oh = - 4 ma, i ol = 4 ma ? when this pin is used as an i 2 c pin, the digital output p - ch transistor is always off digital output digital output pull - up resistor control digital input standby mode c ontrol digital output digital output pull - up resistor control digital input standby mode c ontrol analog input input control p-ch p-ch n-ch r p-ch p-ch n-ch r
document number: 001 - 99224 rev.** page 38 of 115 s6e1b3 series preliminary type circuit remarks h ? cmos level output ? cmos level hysteresis input ? with input control ? analog input ? 5 v tolerant ? with pull - up resistor control ? with standby mode control ? pull - up resistor : approximately 33 k ? i oh = - 4 ma, i ol = 4 ma ? available to control of pzr registers. ? when this pin is used as an i 2 c pin, the digital output p - ch transistor is always off i ? cmos level output ? cmos level hysteresis input ? 5 v tolerant ? with pull - up resistor control ? with standby mode control ? pull - up resistor : approximately 33 k ? i oh = - 4 ma, i ol = 4 ma ? available to control pzr registers ? when this pin is used as an i 2 c pin, the digital output p - ch transistor is always off digital output digital output pull - up resistor control digital input standby mode c ontrol analog input input control digital output digital output pull - up resistor control digital input standby mode c ontrol p-ch p-ch n-ch r p-ch p-ch n-ch r
document number: 001 - 99224 rev.** page 39 of 115 s6e1b3 series preliminary type circuit remarks j ? cmos level hysteresis input k it is possible to select the usb i/o / gpio function. when the usb i/o is selected. ? full - speed, low - speed control when the gpio is selected. ? cmos level output ? cmos level hysteresis input ? with standby mode control udp0/p 0c udm0/ p0b di f ferential mode input gpio digital output gpio digital input/output direction gpio digital input gpio digital input circuit control udp output usb full - speed/low - speed control udp input differential input usb/gpio select udm input udm output usb digital input/output direction gpio digital out put gpio digital input/output direction gpio digital input gpio digital input circuit control
document number: 001 - 99224 rev.** page 40 of 115 s6e1b3 series preliminary 6. handling precautions any semiconductor devices have inherently a certain rate of failure. the possibility of failure is greatly affected by the co nditions in which they are used (circuit conditions, environmental conditions, etc.). this page describes precautions that must be observed to minimize the chance of failure and to obtain higher reliability from your spansion semiconductor devices. 6.1 precautions for product design this section des cribes precautions when designing electronic equipment using semiconductor devices. absolute maximum ratings semiconductor devices can be permanently damaged by application of stress (voltage, current, temperature, etc.) in excess of certain established li mits, called absolute maximum ratings. do not exceed these ratings. recommended operating conditions recommended operating conditions are normal operating ranges for the semiconductor device. all the device's electrical characteristics are warranted when o perated within these ranges. always use semiconductor devices within the recommended operating conditions. operation outside these ranges may adversely affect reliability and could result in device failure. no warranty is made with respect to uses, operating conditions, or combinations not represented on the data sheet. users considering application outside the listed conditions are advised to contact their sales representative beforehand. processing and protection of pins these precautions must be f ollowed when handling the pins which connect semiconductor devices to power supply and input/output functions. (1) preventing over - voltage and over - current conditions exposure to voltage or current levels in excess of maximum ratings at any pin is likely t o cause deterioration within the device, and in extreme cases leads to permanent damage of the device. try to prevent such overvoltage or over - current conditions at the design stage. (2) protection of output pins shorting of output pins to supply pins or o ther output pins, or connection to large capacitance can cause large current flows. such conditions if present for extended periods of time can damage the device. therefore, avoid this type of connection. (3) handling of unused input pins unconnected input pins with very high impedance levels can adversely affect stability of operation. such pins should be connected through an appropriate resistance to a power supply pin or ground pin.
document number: 001 - 99224 rev.** page 41 of 115 s6e1b3 series preliminary latch - up semiconductor devices are constructed by the formation of p - type and n - type areas on a substrate. when subjected to abnormally high voltages, internal parasitic pnpn junctions (called thyristor structures) may be formed, causing large current levels in excess of several hundred ma to flow continuously at the powe r supply pin. this condition is called latch - up. caution: the occurrence of latch - up not only causes loss of reliability in the semiconductor device, but can cause injury or damage from high heat, smoke or flame. to prevent this from happening, do the foll owing: (1) be sure that voltages applied to pins do not exceed the absolute maximum ratings. this should include attention to abnormal noise, surge levels, etc. (2) be sure that abnormal current flows do not occur during the power - on sequence. observance o f safety regulations and standards most countries in the world have established standards and regulations regarding safety, protection from electromagnetic interference, etc. customers are requested to observe applicable regulations and standards in the de sign of products. fail - safe design any semiconductor devices have inherently a certain rate of failure. you must protect against injury, damage or loss from suc h failures by incorporating safety design measures into your facility and equipment such as redundancy, fire protection, and prevention of over - current levels and other abnormal operating conditions. precautions related to usage of devices spansion semiconductor devices are intended for use in standard applications (computers, office automation a nd other office equipment, industrial, communications, and measurement equipment, personal or household devices, etc.). caution: customers considering the use of our products in special applications where failure or abnormal operation may direct ly affect h uman lives or cause physical injury or property damage, or where extremely high levels of reliability are demanded (such as aerospace systems, atomic energy controls, sea floor repeaters, vehicle operating controls, medical devices for life support, etc.) are requested to consult with sales representatives before such use. the company will not be responsible for damages arising from such use without prior approval. 6.2 precautions for package mounting package mounting may be either lead insertion type or surfac e mount type. in either case, for heat resistance during soldering, you should only mount under spansion 's recommended conditions. for detailed information about mount conditions, contact your sales representative. lead insertion type mounting of lead inse rtion type packages onto printed circuit boards may be done by two methods: direct soldering on the board, or mounting by using a socket. direct mounting onto boards normally involves processes for inserting leads into through - holes on the board and using the flow soldering (wave soldering) method of applying liquid solder. in this case, the soldering process usually causes leads to be s ubjected to thermal stress in excess of the absolute ratings for storage temperature. mounting processes should conform to spansion recommended mounting conditions. if socket mounting is used, differences in surface treatment of the socket contacts and ic lead surfaces can lead to contact deterioration after long periods. for this reason it is recommended that the surface tre atment of socket contacts and ic leads be verified before mounting.
document number: 001 - 99224 rev.** page 42 of 115 s6e1b3 series preliminary surface mount type surface mount packaging has longer and thinner leads than lead - insertion packaging, and therefore leads are more easily deformed or bent. the use of packages with high er pin counts and narrower pin pitch results in increased susceptibility to open connections caused by deformed pins, or shorting due to solder bridges. you must use appropriate mounting techniques. spansion recommends the solder reflow method, and has est ablished a ranking of mounting conditions for each product. users are advised to mount packages in accordance with spansion ranking of recommended conditions. lead - free packaging caution: when ball grid array (bga) packages with sn - ag - cu balls are mounted using sn - pb eutectic soldering, junction strength may be reduced under some conditions of use. storage of semiconductor devices because plastic chip packages are formed from plastic resins, exposure to natural environmental conditions will cause absorpt ion of moisture. during mounting, the application of heat to a package that has absorbed moisture can cause surfaces to peel, reduci ng moisture resistance and causing packages to crack. to prevent, do the following: (1) avoid exposure to rapid temperature cha nges, which cause moisture to condense inside the product. store products in locations where temperature changes are slight. (2) use dry boxes for product storage. products should be stored below 70% relative humidity, and at temperatures between 5 ? c and 30 ? c. w hen you open dry package that recommends humidity 40% to 70% relative humidity. (3) when necessary, spansion packages semiconductor devices in highly moisture - resistant aluminum laminate bags, with a silica gel desiccant. devices should be sealed i n their aluminum laminate bags for storage. (4) avoid storing packages where they are exposed to corrosive gases or high levels of dust. baking packages that have absorbed moisture may be de - moisturized by baking (heat drying). follow the spansion recommen ded conditions for baking. condition: 125c/24 h static electricity because semiconductor devices are particularly susceptible to damage by static electricity, you must take the following preca utions: (1) maintain relative humidity in the working environment between 40% and 70%. use of an apparatus for ion generation may be needed to remove electricity. (2) electrically ground all conveyors, solder vessels, soldering irons and peripheral equipment. (3) eliminate static body electricity by the use o f rings or bracelets connected to ground through high resistance (on the level of 1 m ). wearing of conductive clothing and shoes, use of conductive floor mats and other measures to minimize shock loads is recommended. (4) ground all fixtures and instrumen ts, or protect with anti - static measures. (5) avoid the use of styrofoam or other highly static - prone materials for storage of completed board assemblies.
document number: 001 - 99224 rev.** page 43 of 115 s6e1b3 series preliminary 6.3 precautions for use environment reliability of semiconductor devices depends on ambient temperature and other conditions as described above. for reliable performance, do the following: (1) humidity prolong ed use in high humidity can lead to leakage in devices as well as printed circuit boards. if high hu midity levels are anticipated, consider anti - humi dity processing. (2) discharge of static electricity when high - voltage charges exist close to semiconductor devices, discharges can cause abnormal operation. in such cases, use anti - static measures or processing to prevent discharges. (3) corrosive gases, dust, or oil exposure to corrosive gases or contact with dust or oil may lead to chemical reactions that will adversely affect the device. if you use devices in such conditions, consider ways to prevent such exposure or to protect the devices. (4) radiatio n, including cosmic radiation most devices are not designed for environments involving exposure to radiation or cosmic radiation. users should provide shielding as appropriate. (5) smoke, flame caution: plastic molded devices are flammable, and therefore s hould not be used near combustible substances. if devices begin to smoke or burn, there is danger of the release of toxic gases. customers considering the use of spansion products in other special environmental conditions should consult with sales represe ntatives. please check the latest handling precautions at the following url. http://www.spansion.com/fjdocuments/fj/datasheet/e - ds/ds00 - 00004.pdf
document number: 001 - 99224 rev.** page 44 of 115 s6e1b3 series preliminary 7. handling devices power supply pins in products with multiple v cc and v ss pins, respective pins at the same potential are interconnected within the device in order to prevent malfunctions such as latch - up. however, all of these pins should be connected externally to the power supply or ground lines in order to reduce electromagnetic emission levels, to prevent a bnormal operation of strobe signals caused by the rise in the ground level, and to conform to the total output current rating. moreover, connect the current supply source with each power supply pin and gnd pin of this device at low impedance. it is also ad visable that a ceramic capacitor of approximately 0.1 f be connected as a bypass capacitor between each power supply pin and gnd pin , between avcc pin and avss pin near this device. stabilizing supply voltage a malfunction may occur when the power supply voltage fluctuates rapidly even though the fluctuation is within the recommended operating conditions of the vcc power supply voltage. as a rule, with voltage stabilization, suppress the voltage fluctuation so that the fluctuation in vcc ripple ( peak - to - pe ak value) at the commercial frequency (50 hz/60 hz) does not exceed 10% of the vcc value in the recommended operating conditions, and the transient fluctuation rate does not exceed 0.1 v/s when there is a momentary fluctuation on switching the power suppl y. crystal oscillator circuit noise near the x0 /x1 and x0a/ x1 a pins may cause the device to malfunction. design the printed circuit board so that x0 / x1, x0a/x1a pins, the crystal oscillator, and the bypass capacitor to ground are located as close to the de vice as possible. it is strongly recommended that the pc board artwork be designed such that the x0 /x1 and x0a/ x1 a pins are surrounded by ground plane as this is expected to produce stable operation. evaluate oscillation of your using crystal oscillator by your mount board. sub crystal oscillator this series sub oscillator circuit is low gain to keep the low current consumption. the crystal oscillator to fill the follow ing conditions is recommended for sub crystal oscillator to stabilize the oscillation. ? su rface mount type size: more than 3.2 mm 1.5 mm load capacitance: approxima tely 6 pf to 7 pf ? lead type load capacitance: approximately 6 pf to 7 pf
document number: 001 - 99224 rev.** page 45 of 115 s6e1b3 series preliminary using an external clock when using an external cloc k as an input of the main clock , set x0 / x1 to the external clock input, and input the clock to x0 . x1 (pe3) can be used as a general - purpose i/o port. similarly, w hen using an external cloc k as an input of the sub clock , set x0 a/ x1 a to the external clock input, and input the clock to x0 a. x1 a (p47) can be used as a general - purpose i/o port. handling when using multi - function serial pin as i 2 c pin if it is using the multi - function serial pin as i 2 c pins, p - ch transistor of digital output is always disable d . however, i 2 c pins need to keep the electrical characteristic like other pins and not to connect to the external i 2 c bus system with power off. c pin this series contains the regulator. be sure to connect a smoothing capacitor (c s ) for the regulator between the c pin and the gnd pin. please use a ceramic capacitor or a capacitor of equivalent frequency characteristics as a smoothing capacitor. how ever, some laminated ceramic capacitors have the characteristics of capacitance variation due to thermal fluctuation (f characteristics and y5v characteristics). please select the capacitor that meets the specifications in the operating conditio ns to use b y evaluating the temperature characteristics of a capacitor. a smoothing capacitor of about 4.7 f would be recommended for this series. mode pins (md0) connect the md pin (md0) directly to v cc or v ss pins. design the printed circuit board such that the pull - up/down resistance stays low, as well as the distance between the mode pins and v cc pins or v ss pins is as short as possible and the connection impedance is low, when the pins are pulled - up/down such as for switchin g the pin level and rewriting the flash memory data. it is because of preventing the device erroneously switching to test mode due to noise. example of using an external clock device x0 ( x0a ) x1 (pe3), x1a (p47) can be used as general - purpose i/o ports. c s device c vss gnd set as external clock input
document number: 001 - 99224 rev.** page 46 of 115 s6e1b3 series preliminary notes on power - on turn power on/off in the following order or at the same time. turning on : vbat serial communication there is a possibility to receive wrong data due to the noise or other causes on the serial communication. therefore, design a printed circuit board so as to avoid noise. consi der the case of receiving wrong data due to noise ; perform error detection such as by applying a checksum of data at the end. if an error is detected , retransmit the data. differences in features among the products with different memory sizes and between flash memory products and mask products the electric characteristics including power consumption, esd, latch - up, noise characteristics, and oscillation characteristics among the products with different memory sizes and between flash memory products and mas k products are different because chip layout and memory structures are different. if you are switching to use a different product of the same series, please make sure to evaluate the electric characteristics . pull - up function of 5 v tolerant i/o please do not input the signal more than vcc voltage at the time of pull - up function use of 5 v tolerant i / o. handling when using debug pins when debug pins ( swdio/swclk ) are set to gpio or other peripheral functions, set them as output only; do not set them as inpu t.
document number: 001 - 99224 rev.** page 47 of 115 s6e1b3 series preliminary 8. block diagram sw - dp cortex - m0+ core @40 mhz(max) nvic dual - timer watchdog timer (software) clock reset generator watchdog timer (hardware) csv main osc sub osc pll cr 4mhz cr 100khz source clock unit 0 12 - bit a/d converter base timer 16 - bit 16ch. 32 - bit 8ch. a/d activation compare 3ch. 16 - bit input capture 4ch. 16 - bit free - run timer 3ch. 16 - bit output compare 6ch. waveform generator 3ch. 16 - bit ppg 3ch. multi - function timer system rom table ahb - apb bridge bit band wrapper multi - layer ahb (max 40 mhz) fast gpio mtb flash i/f security on - chip sram 64 kbyte on - chip flash 560 kbyte dstc 64ch. ahb - ahb bridge ahb - apb bridge: apb1 (max 40 mhz) crout x1a x0a x1 x0 initx swclk swdio avcc avss avrh avrl anxx adtg tioax tiobx icox frckx dtti0x rto0x igtrgx lvd ctrl power - on reset lvd regulator irq - monitor watch counter real - time clock external interrupt controller 24pin + nmi mode - ctrl low - speed cr prescaler peripheral clock gating gpio pin - function - ctrl multi - function serial i/f 8ch. (with fifo) i2s clock generator 2ch. smart card i/f 2ch. c rtcco subout intx nmix md0 md1 to fast gpio p0x p1x . pxx sckx sinx sotx scsx mi2sckx mi2swsx icx_clk icx_vcc icx_vpen icx_rst icx_cin icx_data s6e1b36g usb2.0 (host/device) phy uhconx0 udp0, udm0 portctl vbat domain vbat domain vwakeup vregctl deep standby ctrl wkupx crc accelerator to pin - function - ctrl
document number: 001 - 99224 rev.** page 48 of 115 s6e1b3 series preliminary 9. memory map memory map (1) see "memory map (2)" for the memory size details. 0x41ff_ffff 0xffff_ffff 0xf800_8000 0xf800_0000 iop(single cycle io) 0x4006_2000 0xf000_2000 0x4006_1000 dstc 0xf000_1000 mtb_dwt 0x4005_0000 0xf000_0000 0x4004_0000 usb ch.0 0xe000_0000 0x4003_cb00 0x4003_ca00 i 2 s clock generator 0x4003_c900 smart card i/f 0x4003_c200 0x4003_c100 peripheral clock gating 0x4003_c000 low speed cr prescaler 0x4003_b000 rtc 0x4003_a000 watch counter 0x4003_9000 crc 0x4400_0000 0x4003_8000 mfs 0x4003_7000 reserved 0x4200_0000 0x4003_6000 usb clock generator 0x4003_5000 lvd / ds mode / vref calibration 0x4000_0000 0x4003_4000 hdmi-cec/remote control receiver 0x4003_3000 gpio 0x2400_0000 0x4003_2000 reserved 0x4003_1000 int_req. read 0x2200_0000 0x4003_0000 exti 0x4002_f000 reserved 0x2008_0000 0x4002_e000 cr trim 0x2000_0000 0x4002_8000 0x0010_4000 0x4002_7000 a/dc 0x0010_2000 cr trimming 0x4002_6000 reserved 0x0010_0000 security 0x4002_5000 base timer 0x4002_4000 ppg 0x0008_c000 0x4002_1000 0x4002_0000 mft unit0 0x4001_6000 0x4001_5000 dual timer 0x0000_0000 0x4001_3000 0x4001_2000 sw wdt 0x4001_1000 hw wdt 0x4001_0000 clock/reset 0x4000_1000 0x4000_0000 flash i/f reserved 32mbytes bit band alias reserved reserved reserved cm0+-coresight- mtb(sfr) reserved reserved cortex-m0 private peripherals reserved reserved reserved reserved reserved sram reserved reserved reserved flash reserved reserved 32mbytes bit band alias peripherals
document number: 001 - 99224 rev.** page 49 of 115 s6e1b3 series preliminary memory map (2) *: see " s6e1 b 3 series flash programming manual" to check details of the flash memory. s6e1b36g s6e1b34g 0x2008_0000 0x2008_0000 0x2001_0000 0x2001_0000 0x2000_f000 0x2000_f000 0x2000_8000 0x2000_0000 0x0010_4000 0x0010_4000 0x0010_2000 cr trimming 0x0010_2000 cr trimming 0x0010_0000 security 0x0010_0000 security 0x0008_c000 0x0004_c000 0x0000_0000 0x0000_0000 reserved reserved sram 4 kbytes sram 4 kbytes sram 60 kbytes sram 28 kbytes flash 560 kbytes flash 304 kbytes reserved sa6-9 (8 kbx4) sa0-5 (8 kbx6) sa6-13 (8 kbx8) sa0-5 (8 kbx6) reserved reserved reserved
document number: 001 - 99224 rev.** page 50 of 115 s6e1b3 series preliminary peripheral address map start address end address bus peripheral 0x4000_0000 0x4000_0fff ahb flash memory i/f register 0x4000_1000 0x4000_ffff reserved 0x4001_0000 0x4001_0fff apb0 clock/reset control 0x4001_1000 0x4001_1fff hardware watchdog t imer 0x4001_2000 0x4001_2fff software watchdog t imer 0x4001_3000 0x4001_4fff reserved 0x4001_5000 0x4001_5fff dual - timer 0x4001_6000 0x4001_ffff reserved 0x4002_0000 0x4002_0fff apb1 multi - function t imer unit 0 0x4002_1000 0x4002_3fff reserved 0x4002_4000 0x4002_4fff ppg 0x4002_5000 0x4002_5fff base timer 0x4002_6000 0x4002_6fff reserved 0x4002_7000 0x4002_7fff a/d converter 0x4002_8000 0x4002_dfff reserved 0x4002_e000 0x4002_efff built - in cr trimming 0x4002_f000 0x4002_ffff reserved 0x4003_0000 0x4003_0fff external interrupt controller 0x4003_1000 0x4003_1fff interrupt request batch - read function 0x4003_2000 0x4003_2fff reserved 0x4003_3000 0x4003_3fff gpio 0x4003_4000 0x4003_4fff hdmi - cec / remote control receiver 0x4003_5000 0x4003_5 f ff low - voltage detection / ds mode / vref calibration 0x4003_6 000 0x4003_6f ff usb clock generator 0x4003_ 70 00 0x4003_7fff reserved 0x4003_8000 0x4003_8fff multi - function s erial interface 0x4003_9000 0x4003_9fff crc 0x4003_a000 0x4003_afff watch counter 0x4003_b000 0x4003_bfff r eal - time clock 0x4003_c000 0x4003_c 0 ff low - speed cr prescaler 0x4003_c100 0x4003_c7ff peripheral clock gating 0x4003_ c8 00 0x4003_ f fff reserved 0x4003_c900 0x4003_c9ff smart card interface 0x4003_ca00 0x4003_caff i 2 s clock generator 0x4003_cb00 0x4003_ e fff reserved 0x4004_0000 0x4005_ffff ahb usb ch.0 0x4006_0000 0x4006_0fff reserved 0x4006_1000 0x4006_1fff dstc 0x4006_2000 0x41ff_ffff reserved
document number: 001 - 99224 rev.** page 51 of 115 s6e1b3 series preliminary 10. pin status in each cpu state the terms used for pin status have the following meanings. ? initx=0 this is the period when the initx pin is the "l" level. ? initx=1 this is the period when the initx pin is the "h" level. ? spl=0 this is the status that the standby pin level setting bit (spl) in the standby mode control register (stb_ctl) is set to "0". ? spl=1 this is the status that the standby pin level setting bit (spl) in the standby mode control register (stb_ctl) is set to "1". ? input enabled indicates that the input function can be used. ? internal input fixed at "0" this is the status that the input function cannot be used. internal input is fixed at "l". ? hi - z indicates that the pin drive transistor is disabled and the pin is put in the hi - z state. ? setting disabled indicates that the setting is disabled. ? maintain previous state maintains the state in which a pin was immediately prior to entering the current mode. if a built - in peripheral function is operating, the output follows the peripheral function. if the pin is being used as a port, that output is maintained. ? analog input is enabled indicates that the analog input is enabled. ? trace output indicates that the trace function can be used. ? gpio selected in deep standby mode, pins switch to the general - purpose i/o port.
document number: 001 - 99224 rev.** page 52 of 115 s6e1b3 series preliminary list of pin status pin status type functio n group state upon power - on reset or low - voltag e detection state at initx input state upon device internal reset state in run mode or sleep mode state in timer mode , rtc mode , or stop mode state in deep standby rtc mode or deep standby stop mode state state when return from deep standby mode state power supply unstable power supply stable power supply stable power supply stable power supply stable power supply stable power supply stable - initx = 0 initx = 1 initx = 1 initx = 1 initx = 1 initx = 1 - - - - spl = 0 spl = 1 spl = 0 spl = 1 - a gpio selected setting disabled setting disabled setting disabled maintain previous state maintain previous state hi - z / internal input fixed at 0 gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected main crystal oscillator input pin/ external main clock input selected input enabled input enabled input enabled input enabled input enabled input enabled input enabled input enabled input enabled b gpio selected setting disabled setting disabled setting disabled maintain previous state maintain previous state hi - z / internal input fixed at 0 gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected external main clock input selected setting disabled setting disabled setting disabled maintain previous state maintain previous state hi - z / internal input fixed at 0 maintain previous state hi - z / internal input fixed at 0 maintain previous state main crystal oscillator output pin hi - z / internal input fixed at 0 / i nput enable d hi - z / internal input fixed at 0 hi - z / internal input fixed at 0 maintain previous state/when oscillation stop s * 1 , hi - z / internal input fixed at 0 maintain previous state/when oscillation stop s * 1 , hi - z / internal input fixed at 0 maintain previous state/when oscillation stop s * 1 , hi - z / internal input fixed at 0 maintain previous state / when oscillation stops*1, hi - z / internal input fixed at 0 maintain previous state / when oscillation stops*1, hi - z / internal input fixed at 0 maintain previous state / when oscillation stops*1, hi - z / internal input fixed at 0 c initx input pin pull - up / input enabled pull - up / input enabled pull - up / input enabled pull - up / input enabled pull - up / input enabled pull - up / input enabled pull - up / input enabled pull - up / input enabled pull - up / input enabled d mode input pin input enabled input enabled input enabled input enabled input enabled input enabled input enabled input enabled input enabled
document number: 001 - 99224 rev.** page 53 of 115 s6e1b3 series preliminary pin status type functio n group state upon power - on reset or low - voltag e detection state at initx input state upon device internal reset state in run mode or sleep mode state in timer mode , rtc mode , or stop mode state in deep standby rtc mode or deep standby stop mode state state when return from deep standby mode state power supply unstable power supply stable power supply stable power supply stable power supply stable power supply stable power supply stable - initx = 0 initx = 1 initx = 1 initx = 1 initx = 1 initx = 1 - - - - spl = 0 spl = 1 spl = 0 spl = 1 - e gpio selected setting disabled setting disabled setting disabled maintain previous state maintain previous state hi - z / internal input fixed at 0 input enabled input enabled input enabled sub crystal oscillator input pin / external sub clock input selected input enabled input enabled input enabled input enabled input enabled input enabled gpio selected hi - z / input enabled gpio selected f gpio selected setting disabled setting disabled setting disabled maintain previous state maintain previous state hi - z / internal input fixed at 0 gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected external sub clock input selected setting disabled setting disabled setting disabled maintain previous state maintain previous state hi - z / internal input fixed at 0 maintain previous state hi - z / internal input fixed at 0 maintain previous state sub crystal oscillator output pin hi - z / internal input fixed at 0/ i nput enable d hi - z / internal input fixed at 0 hi - z / internal input fixed at 0 maintain previous state maintain previous state /when oscillation stop s * 2 , hi - z / internal input fixed at 0 maintain previous state /when oscillation stop s * 2 , hi - z / internal input fixed at 0 maintain previous state / when oscillation stops*2, hi - z/ inte rnal input fixed at 0 maintain previous state / when oscillation stops*2, hi - z/ internal input fixed at 0 maintain previous state / when oscillation stops*2, hi - z/ internal input fixed at 0 g nmix selected setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state wkup input enabled hi - z / wkup input enabled gpio selected resourc e other than the above selected hi - z hi - z / input enabled hi - z / input enabled hi - z / internal input fixed at 0 gpio selected
document number: 001 - 99224 rev.** page 54 of 115 s6e1b3 series preliminary pin status type functio n group state upon power - on reset or low - voltag e detection state at initx input state upon device internal reset state in run mode or sleep mode state in timer mode , rtc mode , or stop mode state in deep standby rtc mode or deep standby stop mode state state when return from deep standby mode state power supply unstable power supply stable power supply stable power supply stable power supply stable power supply stable power supply stable - initx = 0 initx = 1 initx = 1 initx = 1 initx = 1 initx = 1 - - - - spl = 0 spl = 1 spl = 0 spl = 1 - h serial wire debug selected hi - z pull - up / input enabled pull - up / input enabled maintain previous state maintain previous state maintain previous state maintain previous state maintain previous state maintain previous state gpio selected setting disabled setting disabled setting disabled hi - z / internal input fixed at 0 gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected i resourc e selected hi - z hi - z / input enabled hi - z / input enabled maintain previous state maintain previous state hi - z / internal input fixed at 0 gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected gpio selected j external interrupt enabled selected setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected resourc e other than the above selected hi - z hi - z / input enabled hi - z / input enabled hi - z / internal input fixed at 0 gpio selected k analog input selected hi - z hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled resourc e other than the above selected setting disabled setting disabled setting disabled maintain previous state maintain previous state hi - z / internal input fixed at 0 gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected gpio selected
document number: 001 - 99224 rev.** page 55 of 115 s6e1b3 series preliminary pin status type functio n group state upon power - on reset or low - voltag e detection state at initx input state upon device internal reset state in run mode or sleep mode state in timer mode , rtc mode , or stop mode state in deep standby rtc mode or deep standby stop mode state state when return from deep standby mode state power supply unstable power supply stable power supply stable power supply stable power supply stable power supply stable power supply stable - initx = 0 initx = 1 initx = 1 initx = 1 initx = 1 initx = 1 - - - - spl = 0 spl = 1 spl = 0 spl = 1 - l analog input selected hi - z hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled external interrupt enabled selected setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected / internal input fixed at 0 resourc e other than the above selected hi - z / internal input fixed at 0 gpio selected m mode input pin input enabled input enabled input enabled input enabled input enabled input enabled input enabled input enabled input enabled gpio selected setting disabled setting disabled setting disabled maintain previous state maintain previous state hi - z / input enabled gpio selected hi - z / input enabled gpio selected
document number: 001 - 99224 rev.** page 56 of 115 s6e1b3 series preliminary pin status type functio n group state upon power - on reset or low - voltag e detection state at initx input state upon device internal reset state in run mode or sleep mode state in timer mode , rtc mode , or stop mode state in deep standby rtc mode or deep standby stop mode state state when return from deep standby mode state power supply unstable power supply stable power supply stable power supply stable power supply stable power supply stable power supply stable - initx = 0 initx = 1 initx = 1 initx = 1 initx = 1 initx = 1 - - - - spl = 0 spl = 1 spl = 0 spl = 1 - n analog input selected hi - z hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled wkup enabled setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state wkup input enabled hi - z / wkup input enabled gpio selected / internal input fixed at 0 external interrupt enabled selected gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 resourc e other than above selected hi - z / internal input fixed at 0 gpio selected o cec enabled setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state maintain previous state maintain previous state maintain previous state wkup enabled setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state wkup input enabled hi - z / wkup input enabled gpio selected / internal input fixed at 0 external interrupt enabled selected gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 resourc e other than above selected hi - z hi - z / input enabled hi - z / input enabled hi - z / internal input fixed at 0 gpio selected
document number: 001 - 99224 rev.** page 57 of 115 s6e1b3 series preliminary pin status type functio n group state upon power - on reset or low - voltag e detection state at initx input state upon device internal reset state in run mode or sleep mode state in timer mode , rtc mode , or stop mode state in deep standby rtc mode or deep standby stop mode state state when return from deep standby mode state power supply unstable power supply stable power supply stable power supply stable power supply stable power supply stable power supply stable - initx = 0 initx = 1 initx = 1 initx = 1 initx = 1 initx = 1 - - - - spl = 0 spl = 1 spl = 0 spl = 1 - p analog input selected hi - z hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled hi - z / internal input fixed at 0 / analog input enabled wkup enabled setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state wkup input enabled hi - z / wkup input enabled gpio selected / internal input fixed at 0 resourc e other than the above selected hi - z / internal input fixed at 0 gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected q external interrupt enabled selected setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected usb io hi/ - z/input enabled hi/ - z/input enabled hi - z/input enabled hi - z/input enabled hi - z/input enabled gpio selected hi - z hi - z/input enabled hi - z/input enabled maintain previous state hi - z gpio hi - z gpio r cec enabled setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state maintain previous state maintain previous state maintain previous state external interrupt enabled selected setting disabled setting disabled setting disabled maintain previous state maintain previous state maintain previous state gpio selected / internal input fixed at 0 hi - z / internal input fixed at 0 gpio selected / internal input fixed at 0 resourc e other than above selected hi - z hi - z / input enabled hi - z / input enabled hi - z / internal input fixed at 0 gpio selected *1: oscillation stops in s ub timer mode , low - speed cr timer mode, stop mode, rtc mode. *2: oscillation stop s in stop mode.
document number: 001 - 99224 rev.** page 58 of 115 s6e1b3 series preliminary 11. electrical characteristics 11.1 absolute maximum ratings parameter symbol rating unit remarks min max power supply voltage* 1, * 2 v cc v ss - 0.5 v ss + 4.6 v analog power supply voltage * 1, * 3 av cc v ss - 0.5 v ss + 4.6 v analog reference voltage* 1, * 3 avrh v ss - 0.5 v ss + 4.6 v input voltage* 1 v i v ss - 0.5 v cc + 0.5 ( 4.6 v) v v ss - 0.5 v ss + 6.5 v 5 v tolerant analog pin input voltage* 1 v ia v ss - 0.5 v cc + 0.5 ( 4.6 v) v output voltage* 1 v o v ss - 0.5 v cc + 0.5 ( 4.6 v) v l level maximum output current* 4 i ol - 10 ma 39 ma p0b / p0c l level average output current* 5 i olav - 4 ma l level total maximum output current i ol - 100 ma l level total average output current* 6 i olav - 50 ma h level maximum output current* 4 i oh - - 10 ma - 39 ma p0b / p0c h level average output current* 5 i ohav - - 4 ma h level total maximum output current i oh - - 100 ma h level total average output current* 6 i ohav - - 50 ma power consumption p d - 250 mw storage temperature t stg - 55 + 150 c *1: these parameters are based on the condition that v ss = a v ss = 0 v. *2: v cc must not drop below v ss - 0.5 v. * 3 : ensure that the voltage does not to exceed v cc + 0. 5 v at power - on . * 4 : the maximum output current is the peak value for a single pin. * 5 : the average output is the average current for a single pin over a period of 100 ms. * 6 : the total average output current is the average current for all pins over a period of 100 ms. * 7 : when p0c/udp0 and p0b/udm0 pins are used as gpio (p0c, p0b). *8: when p0c/udp0 and p0b/udm0 pins are used as usb (udp0, udm0) . < warning > ? semiconductor devices can be permanently damaged by application of stress (voltage, current, temperature, etc.) in excess of absolute maximum ratings. do not exceed these ratings.
document number: 001 - 99224 rev.** page 59 of 115 s6e1b3 series preliminary 11.2 recommended operating condi tions (v ss = a v ss = 0.0 v) parameter symbol conditions value unit remarks min max power supply voltage v cc - 1.65 * 3 3.6 v 3.0 3.6 v * 1 sub oscillation frequency fin - - - khz t ypical is 32.768 khz analog power supply voltage av cc - 1.65 3.6 v av cc = v cc analog reference voltage avrh - 2.7 av cc v av cc cc av cc v av cc < 2.7 v avrl - av ss av ss v smoothing capacitor c s - 1 10 f 2 operating t emperature t a - - 40 + 10 5 c * 1 : when p 0c/ udp0 and p0 b /udm0 pins are used as usb (udp0, udm0). * 2 : see "c pin" in " 7 . handling devices " for the connection of the smoothing capacitor. * 3 : in between less than the minimu m power supply voltage reset / interrupt detection voltage or more, instruction execution and low voltage detection function by built - in high - speed cr (including main pll is used) or built - in low - speed cr is possible to operate only. < warning > 1. the recomm ended operating conditions are required in order to ensure the normal operation of the semiconductor device. all of the device's electrical characteristics are warranted when the device is operated within these ranges. 2. always use semiconductor devices with in their recommended operating condition ranges. operation outside these ranges may adversely affect reliability and could result in device failure. 3. no warranty is made with respect to uses, operating conditions, or combinations not represented on the data sheet. 4. users considering application outside the listed conditions are advised to contact their representatives beforehand.
document number: 001 - 99224 rev.** page 60 of 115 s6e1b3 series preliminary 11.3 dc characteristics 11.3.1 current rating symbol (pin name ) conditions hclk frequency *4 value unit remarks typ *1 max *2 i cc (vcc) run mode, code executed from flash 4 mhz external clock input, pll on *8 nop code executed built - in high speed cr stopped all peripheral clock stopped by ckenx 4 mh z 0.7 tbd ma *3 8 mh z 1.15 tbd 20 mh z 2.25 tbd 40 mh z 4.5 tbd 4 mhz external clock input, pll on *8 benchmark code executed built - in high speed cr stopped pclk1 stopped 4 mh z 0.75 tbd ma *3 8 mh z 1.25 tbd 20 mh z 2.5 tbd 40 mh z 5 .0 tbd 4 mhz crystal oscillation, pll on *8 nop code executed built - in high speed cr stopped all peripheral clock stopped by ckenx 4 mh z 0.8 tbd ma *3 8 mh z 1.4 tbd 20 mh z 2.75 tbd 40 mh z 5.5 tbd run mode, code executed from ram 4 mhz external clock input, pll on *8 nop code executed built - in high speed cr stopped all peripheral clock stopped by ckenx 4 mh z 0.6 tbd ma *3 8 mh z 1.2 tbd 20 mh z 2.4 tbd 40 mh z 4.8 tbd run mode, code executed from flash 4 mhz external clock input, pll on nop code executed built - in high speed cr stopped pclk1 stopped 40 mh z 2.6 tbd ma *3 ,*6,*7 run mode, code executed from flash built - in high speed cr *5 nop code executed all peripheral clock stopped by ckenx 4 mh z 1.2 tbd ma *3 32 khz crystal oscillation nop code executed all peripheral clock stopped by ckenx 32 k h z 96 tbd a *3 built - in low speed cr nop code executed all peripheral clock stopped by ckenx 100 k h z 120 tbd a *3 i ccs (vcc) sleep operation 4 mhz external clock input, pll on *8 all peripheral clock stopped by ckenx 4 mh z 0.6 tbd ma *3 8 mh z 1.1 tbd 20 mh z 1.9 tbd 40 mh z 3.2 tbd built - in high speed cr *5 all peripheral clock stopped by ckenx 4 mh z 0.5 tbd ma *3 32 khz crystal oscillation all peripheral clock stopped by ckenx 32 k h z 94 tbd a *3 built - in low speed cr all peripheral clock stopped by ckenx 100 k h z 105 tbd a *3 *1 : t a =+25 c , v cc =3. 3 v *2 : t a =+ 10 5 c , v cc =3.6 v *3 : all ports are fixed *4 : pclk0 is set to divided rate 8 *5 : the frequency is set to 4 mhz by trimming *6 : flash sync down is set to frwtr.rwt=11 and fsyndn.sd=1111 *7 : vcc= 1 . 65 v *8 : when hclk=4 mhz, pll off
document number: 001 - 99224 rev.** page 61 of 115 s6e1b3 series preliminary parameter symbol (pin name ) conditions value unit remarks typ max power supply current i cch (vcc) stop mode t a =25 c v cc = 3.3 v 10 tbd a *1 t a =25 c v cc = 1.65 v 9 tbd a *1 t a = 10 5 c v cc = 3.6 v - tbd a *1 i cct (vcc) sub timer mode t a =25 c v cc = 3. 3 v 32 khz crystal oscillation 13 tbd a *1 t a =25 c v cc = 1.65 v 32 khz crystal oscillation 12 tbd a *1 t a = 10 5 c v cc = 3.6 v 32 khz crystal oscillation - tbd a *1 i ccr (vcc) rtc mode t a =25 c v cc = 3. 3 v 32 khz crystal oscillation 10.5 tbd a *1 t a =25 c v cc = 1.65 v 32 khz crystal oscillation 9.5 tbd a *1 t a = 10 5 c v cc = 3.6 v 32 khz crystal oscillation - tbd a *1 *1: a l l ports are fixed. lvd off. flash off.
document number: 001 - 99224 rev.** page 62 of 115 s6e1b3 series preliminary parameter symbol (pin name ) conditions value unit remarks typ max power supply current i cchd (vcc) deep standby stop mode ram off t a =25 c v cc = 3.3 v 0.75 tbd a *1 t a =25 c v cc = 1.65 v 0.7 tbd a *1 t a = 105 c v cc = 3.6 v - tbd a *1 ram o n t a =25 c v cc = 3.3 v 1.1 tbd a *1 t a =25 c v cc = 1.65 v 1.0 tbd a *1 t a = 105 c v cc = 3.6 v - tbd a *1 i ccrd (vcc) deep standby rtc mode ram off t a =25 c v cc = 3.3 v 1.7 tbd a *1 t a =25 c v cc = 1.65 v 1.6 tbd a *1 t a = 105 c v cc = 3.6 v - tbd a *1 ram o n t a =25 c v cc = 3.3 v 1.9 tbd a *1 t a =25 c v cc = 1.65 v 1.7 tbd a *1 t a = 105 c v cc = 3.6 v - tbd a *1 *1: a l l ports are fixed. lvd off.
document number: 001 - 99224 rev.** page 63 of 115 s6e1b3 series preliminary parameter symbol (pin name ) conditions value unit remarks typ max power supply current i ccvbat (vbat) rtc operation t a =25 c v cc = 3.0 v 32 khz crystal oscillation 0.9 tbd a *1 t a =25 c v cc = 1.65 v 32 khz crystal oscillation 0.8 tbd a *1 t a = 10 5 c v cc = 3.6 v 32 khz crystal oscillation - tbd a *1 rtc stop t a =25 c v cc = 3.0 v 0.05 tbd a *1 t a =25 c v cc = 1.65 v 0.02 tbd a *1 t a = 10 5 c v cc = 3.6 v - tbd a *1 *1: a l l ports are fixed.
document number: 001 - 99224 rev.** page 64 of 115 s6e1b3 series preliminary lvd current ( v cc = 1.65 v to 3.6 v, v ss = a v ss = 0 v, t a = - 40c to + 10 5 c) parameter symbol pin name conditions value unit remarks typ max low - v oltage detection circuit (lvd) power supply current i cclvd vcc at operation 0.13 tbd flash memory current ( v cc = 1.65 v to 3.6 v, v ss = a v ss = 0 v, t a = - 40c to + 10 5 c) parameter symbol pin name conditions value unit remarks typ max flash m emory w rite/ e rase current i ccflash vcc at write/erase 9.5 tbd ma a/d converter current ( v cc = 1.65 v to 3.6 v, v ss = a v ss = 0 v, t a = - 40c to + 10 5 c) parameter symbol pin name conditions value unit remarks typ max power supply current i ccad avcc at operation 0.7 tbd ma at stop 0.13 tbd ccavrh avrh at operation 1.1 tbd ma avrh=3.6 v at stop 0.1 tbd
document number: 001 - 99224 rev.** page 65 of 115 s6e1b3 series preliminary peripheral current dissipation ( v cc = 3. 3 v, t a = 2 5 c) clock system peripheral conditions frequency (mhz) unit remarks 4 8 20 40 hclk gpio at a ll ports operation 0.02 0.04 0.11 0.22 ma dstc at 2ch operation 0.07 0.15 0.37 0.74 pclk1 base timer at 4ch operation 0.02 0.04 0.08 0.16 ma multi - functional timer/ppg at 1 unit/4ch operation 0.06 0.11 0.28 0.55 adc at 1 unit operation 0.02 0.04 010 0.20 multi - function serial at 1ch operation 0.03 0.06 0.16 0.31 11.3.2 pin characteristics (v cc = a v cc = 1.65 v to 3.6 v, v ss = a v ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions value unit remarks min typ max h level input voltage (hysteresis input) v ihs cmos hysteresis input pin, md0, md1 v cc cc 0.8 - v cc + 0.3 v v cc < 2.7 v v cc 0. 7 5 v tolerant input pin v cc cc 0.8 - v ss + 5.5 v v cc < 2.7 v v cc 0. 7 l level input voltage (hysteresis input) v ils cmos hysteresis input pin, md0, md1 v cc ss - 0.3 - v cc 0.2 v v cc < 2.7 v v cc 0. 3 5 v tolerant input pin v cc ss - 0.3 - v cc 0.2 v v cc < 2.7 v v cc 0. 3 h level output voltage v oh 4 ma type v cc oh = - 4 ma v cc - 0.5 - v cc v v cc < 2.7 v , i oh = - 2 ma v cc - 0. 4 5 the pin doubled as usb i/o - usb v cc - 0. 4 - usb v cc v l level output voltage v ol 4 ma type v cc ol 4 ma v ss - 0.4 v v cc < 2.7 v , i ol = 2 ma the pin doubled as usb i/o - v ss - 0.4 v input leak current i il - - - 5 - + 5 pull - up resistance value r pu pull - up pin v cc v cc < 2.7 v - - 134 input capacitance c in other than vcc, usbvcc, vss, avcc, avss, avrh - - 5 15 pf
document number: 001 - 99224 rev.** page 66 of 115 s6e1b3 series preliminary 11.4 ac characteristics 11.4.1 main clock input characteristics (v cc = a v cc = 1.65 v to 3.6 v, v ss = a v ss = 0 v, t a = - 40c to + 10 5 c) parameter symbol pin name conditions value unit remarks min max input frequency f ch x0, x1 v cc cc < 2.7 v 4 20 - 4 4 8 mhz when the external c lock is used input clock cycle t cylh - 20.83 250 ns when the external c lock is used input clock pulse width - p wh /t cylh , p wl /t cylh 45 55 % when the external c lock is used input clock ris ing time and fall ing time t cf, t cr - - 5 ns when the external c lock is used internal operating c lock *1 frequency f cm - - - 40 .8 mhz master clock f cc - - - 40 .8 mhz base clock (hclk/fclk) f cp0 - - - 40 .8 mhz apb0 bus clock* 2 f cp1 - - - 40 .8 mhz apb1 bus clock* 2 internal operating clock *1 cycle time t cycc - - 2 4. 5 - ns base clock (hclk/fclk) t cycp0 - - 2 4. 5 - ns apb0 bus clock* 2 t cycp1 - - 2 4. 5 - ns apb1 bus clock* 2 *1: for details of each internal operating clock , refer to " chapter : clock " in " fm 0 + family peripheral manual ". *2: for details of the apb bus to which a peripheral is connected , see " 8 . block diagram ". x0
document number: 001 - 99224 rev.** page 67 of 115 s6e1b3 series preliminary 11.4.2 sub clock input characteristics (v cc = a v cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions value unit remarks min typ max input frequency f cl x0a, x1a - - 32.768 - khz when the crystal oscillator is connected * - 32 - 100 khz when the external c lock is used input clock cycle t cyll - 10 - 31.25 wh /t cyll , p wl /t cyll 45 - 55 % when the external c lock is used *: see " s ub crystal oscillator " in " 7 . handling devices " for the crystal oscillator used. x0 a
document number: 001 - 99224 rev.** page 68 of 115 s6e1b3 series preliminary 11.4.3 built - in cr oscillation characteristics built - in high - speed cr (v cc = a v cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol conditions value unit remarks min typ max clock frequency f crh t a = - 20 c to +85 c 3.9 6 4 4.0 4 mhz during trimming *1 t a = - 4 0 c to + 105 c 3.92 4 4.08 t a = - 40c to + 105 c 2. 6 4 5.2 not during trimming frequency stabilization time t crwt - - - 30 *2 300 *2 *1: in the case of using the values in cr trimming area of flash memory at shipment for frequency trimming/temperature trimming. *2: this is time from the trim value setting to stable of the frequency of the h igh - speed cr clock. after setting the trim value, the period when the frequency stability time passes can use the h igh - speed cr clock as a source clock. built - in low - speed cr (v cc = a v cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol conditions value unit remarks min typ max clock frequency f crl - 50 100 150 k hz
document number: 001 - 99224 rev.** page 69 of 115 s6e1b3 series preliminary 11.4.4 operating conditions of main pll ( in the case of using the main clock as the input clock of the pll ) (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol value unit remarks min typ max pll oscillation stabilization wait time* 1 (lock up time) t lock 100 - - pll input clock frequency f plli 4 - 16 mh z pll multiple rate - 5 - 37 multiple pll macro oscillation clock frequency f pllo 75 - 150 mh z main pll clock frequency* 2 f clkpll - - 40 .8 mh z usb clock frequency* 3 f clk s pll - - 4 8 mh z * 1 : the wait time is the time it takes for pll oscillation to stabilize. *2: for details of the main pll clock (clkpll), refer to " chapter : clock" in "fm0+ family peripheral manual ". *3: for more information about usb clock, see "chapter: usb clock generation" in "fm 0+ family peripheral manual communication macro part. 11.4.5 operating conditions of main pll (in the case of using the built - in high - speed cr clock as the input clock of the main pll) (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol value unit remarks min typ max pll oscillation stabilization wait time* 1 (lock up time) t lock 100 - - pll input clock frequency f plli 3.8 4 4.2 mh z pll multiple rate - 19 - 35 multiple pll macro oscillation clock frequency f pllo 72 - 150 mh z main pll clock frequency* 2 f clkpll - - 40 .8 mh z * 1 : the wait time is the time it takes for pll oscillation to stabilize. *2: for details of the main pll clock (clkpll), refer to " chapter : clock" in "fm0+ family peripheral manual ". note: ? for the main pll source clock, i npu t the high - speed cr clock (clkhc) whose frequency has been trimme d. when setting pll multiple rate, please take the accuracy of the built - in h igh - speed cr cloc k into account and prevent the master clock from exceeding the maximum frequency. high - speed cr clock (clkhc) pll input clock main pll pll macro oscillation clock m divider main pll clock (clkpll) n divider main pll connection main clock (clkmo) k divider
document number: 001 - 99224 rev.** page 70 of 115 s6e1b3 series preliminary 11.4.6 reset input characteristics (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions value unit remarks min max reset input time t initx initx - 500 - ns 11.4.7 power - on reset timing (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name value unit remarks min max power supply rising time t vccr v cc 0 - ms power supply shut down time t off 1 - ms time until releasing power - on reset t prt 0.43 3.4 ms glossary ? vcc_minimum : minimum v cc of recommended operating conditions . ? vd h _minimum : minimum detection voltage of low - v oltage detection reset . see " 11.7 low - voltage d etection ch aracteristics " . main clock (clkmo) k divider pll input clock usb pll m divider usb clock n divider usb pll connection pll macro oscillation clock 0 . 2 v v d h _ m i n i m u m v c c _ m i n i m u m t p r t i n t e r n a l r e s e t v c c c p u o p e r a t i o n s t a r t r e s e t a c t i v e r e l e a s e t v c c r 0 . 2 v 0 . 2 v t o f f
document number: 001 - 99224 rev.** page 71 of 115 s6e1b3 series preliminary 11.4.8 base timer input timing timer input timing (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions value unit remarks min max input pulse width t tiwh , t tiwl tioan/tiobn (when using as eck, tin) - 2 t cycp - ns trigger input timing (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions value unit remarks min max input pulse width t trgh , t trgl tioan/tiobn (when using as tgin) - 2 t cycp - ns note: ? t cycp indicates the apb bus clock cycle time. for the number of the apb bus to which the base timer has been connected , see " 8 . block diagram ". eck tin tgin t tiwh v ihs v ihs v ils v ils t tiw l t trgh v ihs v ihs v ils v ils t trg l
document number: 001 - 99224 rev.** page 72 of 115 s6e1b3 series preliminary 11.4.9 csio /spi/uart timing csio (spi = 0, scinv = 0) (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions v cc < 2.7 v v cc 2.7 v unit min max min max serial clock cycle time t scyc sck x master mode 4 t cycp - 4 t cycp - ns sck sot delay time slovi sckx , sotx - 30 + 30 - 20 + 20 ns sin sck setup time ivshi sckx , sinx 6 0 - 50 - ns sck sin hold time shixi sckx , sinx 0 - 0 - ns serial clock l pulse width t slsh sckx slave mode 2 t cycp - 10 - 2 t cycp - 10 - ns serial clock h pulse width t shsl sckx t cycp + 10 - t cycp + 10 - ns sck sot delay time slove sckx , sotx - 65 - 52 ns sin sck setup time ivshe sckx , sinx 10 - 10 - ns sck sin hold time shixe sckx , sinx 20 - 20 - ns sck falling time t f sckx - 5 - 5 ns sck rising time t r sckx - 5 - 5 ns notes : ? the above ac characteristics are for clock synchronous mode. ? t cycp represents the apb bus clock cycle time. for the number of the apb bus to which multi - function serial has been connected, see " 8 . block diagram ". ? the characteristics are only applicable when the relocate port numbers are the same. for instance, they are not applicable for the combination of sckx_0 and sotx_1. ? external load capacitance c l = 30 pf
document number: 001 - 99224 rev.** page 73 of 115 s6e1b3 series preliminary master mode slave mode t scyc v oh v oh v ol v ol v ol v ih v il v ih v il t slovi t ivshi t shixi sck sot sin t slsh t shsl v ih t f t r v ih v oh v ih v il v il v ol v ih v il v ih v il t slove t ivshe t shixe sck sot sin
document number: 001 - 99224 rev.** page 74 of 115 s6e1b3 series preliminary csio (spi = 0, scinv = 1 ) (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions v cc < 2.7 v v cc 2.7 v unit min max min max serial clock cycle time t scyc sckx master mode 4 t cycp - 4 t cycp - ns sck sot delay time shovi sckx , sotx - 30 + 30 - 20 + 20 ns sin sck setup time ivsli sckx , sinx 6 0 - 50 - ns sck sin hold time slixi sckx , sinx 0 - 0 - ns serial clock l pulse width t slsh sckx slave mode 2 t cycp - 10 - 2 t cycp - 10 - ns serial clock h pulse width t shsl sckx t cycp + 10 - t cycp + 10 - ns sck sot delay time shove sckx , sotx - 65 - 52 ns sin sck setup time ivsle sckx , sinx 10 - 10 - ns sck sin hold time slixe sckx , sinx 20 - 20 - ns sck falling time t f sckx - 5 - 5 ns sck rising time t r sckx - 5 - 5 ns notes : ? the above ac characteristics are for clock synchronous mode. ? t cycp represents the apb bus clock cycle time. for the number of the apb bus to which multi - function serial has been connected, see " 8 . block diagram ". ? the characteristics are only applicable when the r elocate port numbers are the same. for instance, they are not applicable for the combination of sckx_0 and sotx_1. ? external load capacitance c l = 30 pf
document number: 001 - 99224 rev.** page 75 of 115 s6e1b3 series preliminary master mode slave mode t scyc v oh v oh v oh v ol v ol v ih v il v ih v il t shovi t ivsli t slixi sck sot sin t shsl t slsh v ih t f t r v ih v oh v il v il v il v ol v ih v il v ih v il t ivsle t slixe sck sot sin t shove
document number: 001 - 99224 rev.** page 76 of 115 s6e1b3 series preliminary spi (spi = 1, scinv = 0 ) (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions v cc < 2.7 v v cc 2.7 v unit min max min max serial clock cycle time t scyc sckx master mode 4 t cycp - 4 t cycp - ns sck sot delay time shovi sckx , sotx - 30 + 30 - 20 + 20 ns sin sck setup time ivsli sckx , sinx 6 0 - 50 - ns sck sin hold time slixi sckx , sinx 0 - 0 - ns sot sck delay time sovli sckx , sotx 2 t cycp - 30 - 2 t cycp - 30 - ns serial clock l pulse width t slsh sckx slave mode 2 t cycp - 10 - 2 t cycp - 10 - ns serial clock h pulse width t shsl sckx t cycp + 10 - t cycp + 10 - ns sck sot delay time shove sckx , s ot x - 65 - 52 ns sin sck setup time ivsle sckx , sinx 10 - 10 - ns sck sin hold time slixe sckx , sinx 20 - 20 - ns sck falling time t f sckx - 5 - 5 ns sck rising time t r sckx - 5 - 5 ns notes : ? the above ac characteristics are for clock synchronous mode. ? t cycp represents the apb bus clock cycle time. for the number of the apb bus to which multi - function serial has been connected, see " 8 . block diagram ". ? the characteristics are only applicable when the relocate port numbers are the same. for instance, they are not applicable for the combination of sckx_0 and sotx_1. ? external load capacitan ce c l = 30 pf
document number: 001 - 99224 rev.** page 77 of 115 s6e1b3 series preliminary master mode slave mode *: changes when writing to tdr register t sovli t scyc t shovi v ol v ol v oh v oh v o l v oh v o l v ih v i l v ih v i l t ivsli t slixi sck sot sin t f t r t slsh t shsl t shove v i l v i l v ih v ih v ih v oh * v o l v oh v o l v ih v i l v ih v i l t ivsle t slixe sck sot sin
document number: 001 - 99224 rev.** page 78 of 115 s6e1b3 series preliminary spi (spi = 1, scinv = 1 ) (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions v cc < 2.7 v v cc 2.7 v unit min max min max serial clock cycle time t scyc sckx master mode 4 t cycp - 4 t cycp - ns sck sot delay time slovi sckx , sotx - 30 +30 - 20 +20 ns sin sck setup time ivshi sckx , sinx 60 - 50 - ns sck sin hold time shixi sckx , sinx 0 - 0 - ns sot sck delay time sovhi sckx , sotx 2 t cycp - 30 - 2 t cycp - 30 - ns serial clock l pulse width t slsh sckx slave mode 2 t cycp - 10 - 2 t cycp - 10 - ns serial clock h pulse width t shsl sckx t cycp + 10 - t cycp + 10 - ns sck slove sckx , s ot x - 65 - 52 ns sin sck setup time ivshe sckx , sinx 10 - 10 - ns sck sin hold time shixe sckx , sinx 20 - 20 - ns sck falling time t f sckx - 5 - 5 ns sck rising time t r sckx - 5 - 5 ns notes : ? the above ac characteristics are for clock synchronous mode. ? t cycp represents the apb bus clock cycle time. for the number of the apb bus to which multi - function serial has been connected, see " 8 . block diagram ". ? the characteristics are only applicable when the relocate port numbers are the same. for instance, they are not applicable for the combination of sckx_0 and sotx_1. ? external load capacitance c l = 30 pf
document number: 001 - 99224 rev.** page 79 of 115 s6e1b3 series preliminary master mode slave mode t scyc t slovi v ol v oh v oh v oh v o l v oh v o l v ih v i l v ih v i l t ivshi t shixi t sovhi sck sot sin t shsl t r t slsh t f t slove v il v il v il v ih v ih v oh v o l v oh v o l v ih v il v ih v il t ivshe t shixe sck sot sin
document number: 001 - 99224 rev.** page 80 of 115 s6e1b3 series preliminary when using csio/spi chip select (scinv=0 , cslvl=1 ) (v cc = a v cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol conditions v cc < 2.7 v v cc 2.7 v unit min max min max scs cssi master mode (*1) - 5 0 (*1)+0 (*1) - 5 0 (*1)+0 ns sck hold time cshi (*2)+0 (*2)+ 5 0 (*2)+0 (*2)+ 5 0 ns scs deselect time t csdi (*3) - 5 0 (*3)+ 5 0 (*3) - 5 0 (*3)+ 5 0 ns scs csse slave mode 3t cycp + 30 - 3t cycp + 30 - ns sck hold time cshe 0 - 0 - ns scs deselect time t csde 3t cycp + 30 - 3t cycp + 30 - ns scs dse - 55 - 4 3 ns scs dee 0 - 0 - ns *1 : cssu bit value serial chip select timing operating clock cycle . *2 : cshd bit value serial chip select timing operating clock cycle . *3 : csds bit value serial chip select timing operating clock cycle . irrespectiv e of csds bit setting, 5 t cycp or more are required fo r the period the time when the s erial c hip s elect pin becomes inactive to the time when the s erial c hip s elect pin becomes active again. notes : ? t cycp indicates the apb bus clock cycle time. f or information a bout the apb bus number which multi - function serial is connected to, see " 8 . block diagram ". ? for information a bout cssu, cshd, csds, serial chip select timing operating clock, see "fm0+ family peripheral manual ". ? these characteristics only guarantee the same relocate port number. for example, the combination of sckx_0 and s csi x_1 is not guaranteed. ? when the external load capacitance c l = 30 pf.
document number: 001 - 99224 rev.** page 81 of 115 s6e1b3 series preliminary master mode slave mode scso sck sot (spi=0) sot (spi=1) scsi sck sot (spi=0) sot (spi=1) t cssi t cshi t csdi t d s e t csse t cshe t csde t dee
document number: 001 - 99224 rev.** page 82 of 115 s6e1b3 series preliminary when using csio/spi chip select (scinv= 1, cslvl=1 ) (v cc = a v cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol conditions v cc < 2.7 v v cc 2.7 v unit min max min max scs cssi master mode (*1) - 5 0 (*1)+0 (*1) - 5 0 (*1)+0 ns sck hold time cshi (*2)+0 (*2)+ 5 0 (*2)+0 (*2)+ 5 0 ns scs deselect time t csdi (*3) - 5 0 (*3)+ 5 0 (*3) - 5 0 (*3)+ 5 0 ns scs csse slave mode 3t cycp + 30 - 3t cycp + 30 - ns sck hold time cshe 0 - 0 - ns scs deselect time t csde 3t cycp + 30 - 3t cycp + 30 - ns scs dse - 55 - 4 3 ns scs dee 0 - 0 - ns *1 : cssu bit value serial chip select timing operating clock cycle . *2 : cshd bit value serial chip select timing operating clock cycle . *3 : csds bit value serial chip select timing operating clock cycle . irrespectiv e of csds bit setting, 5 t cycp or more are required fo r the period the time when the s erial c hip s elect pin becomes inactive to the time when the s erial c hip s elect pin becomes active again. notes : ? t cycp indicates t he apb bus clock cycle time. for information a bout the apb bus number which multi - function serial is connected to, see " 8 . block diagram ". ? for information a bout cssu, cshd, csds, serial chip select timing operating clock, see "fm0+ family peripheral manual ". ? these characteristics only guarantee the same relocate port number. for example, the combination of sckx_0 and s csi x_1 is not guaranteed. ? when the external load capacitance c l = 30 pf.
document number: 001 - 99224 rev.** page 83 of 115 s6e1b3 series preliminary master mode slave mode scso sck sot (spi=0) sot (spi=1) scsi sck sot (spi=0) sot (spi=1) t cssi t cshi t csdi t d s e t csse t cshe t csde t dee
document number: 001 - 99224 rev.** page 84 of 115 s6e1b3 series preliminary when using csio/spi chip select (scinv= 0, cslvl=0 ) (v cc = a v cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol conditions v cc < 2.7 v v cc 2.7 v unit min max min max scs cssi master mode (*1) - 5 0 (*1)+0 (*1) - 5 0 (*1)+0 ns sck hold time cshi (*2)+0 (*2)+ 5 0 (*2)+0 (*2)+ 5 0 ns scs deselect time t csdi (*3) - 5 0 (*3)+ 5 0 (*3) - 5 0 (*3)+ 5 0 ns scs csse slave mode 3t cycp + 30 - 3t cycp + 30 - ns sck hold time cshe 0 - 0 - ns scs deselect time t csde 3t cycp + 30 - 3t cycp + 30 - ns scs dse - 55 - 4 3 ns scs dee 0 - 0 - ns *1 : cssu bit value serial chip select timing operating clock cycle . *2 : cshd bit value serial chip select timing operating clock cycle . *3 : csds bit value serial chip select timing operating clock cycle . irrespectiv e of csds bit setting, 5 t cycp or more are required fo r the period the time when the s erial c hip s elect pin becomes inactive to the time when the s erial c hip s elect pin becomes active a gain. notes : ? t cycp indicates the apb bus clock cycle time. for information a bout the apb bus number which multi - function serial is connected to, see " 8 . block diagram ". ? for information a bout cssu, cshd, csds, serial chip select timing operating clock, see "fm0+ family peripheral manual ". ? these characteristics only gua rantee the same relocate port number. for example, the combination of sckx_0 and s csi x_1 is not guaranteed. ? when the external load capacitance c l = 30 pf.
document number: 001 - 99224 rev.** page 85 of 115 s6e1b3 series preliminary master mode slave mode scso sck sot (spi=0) sot (spi=1) scsi sck sot (spi=0) sot (spi=1) t cssi t cshi t csdi t d s e t csse t cshe t csde t dee
document number: 001 - 99224 rev.** page 86 of 115 s6e1b3 series preliminary when using csio/spi chip select (scinv= 1, cslvl=0 ) (v cc = a v cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol conditions v cc < 2.7 v v cc 2.7 v unit min max min max scs cssi master mode (*1) - 5 0 (*1)+0 (*1) - 5 0 (*1)+0 ns sck hold time cshi (*2)+0 (*2)+ 5 0 (*2)+0 (*2)+ 5 0 ns scs deselect time t csdi (*3) - 5 0 (*3)+ 5 0 (*3) - 5 0 (*3)+ 5 0 ns scs csse slave mode 3t cycp + 30 - 3t cycp + 30 - ns sck hold time cshe 0 - 0 - ns scs deselect time t csde 3t cycp + 30 - 3t cycp + 30 - ns scs dse - 55 - 4 3 ns scs dee 0 - 0 - ns *1 : cssu bit value serial chip select timing operating clock cycle . *2 : cshd bit value serial chip select timing operating clock cycle . *3 : csds bit value serial chip select timing operating clock cycle . irrespectiv e of csds bit setting, 5 t cycp or more are required fo r the period the time when the s erial c hip s elect pin becomes inactive to the time when the s erial c hip s elect pin becomes active again. notes : ? t cycp indicates the apb bus clock cycle time. for information a bout the apb bus number which multi - function serial is connected to, see " 8 . block diagram ". ? for information a bout cssu, cshd, csds, serial chip select timing operating clock, see "fm0+ family peripheral manual ". ? these characteristics only guarantee the same relocate port number. for example, the combination of sckx_0 and s csi x_1 is not guaranteed. ? when the external load capacitance c l = 30 pf.
document number: 001 - 99224 rev.** page 87 of 115 s6e1b3 series preliminary master mode slave mode scso sck sot (spi=0) sot (spi=1) scsi sck sot (spi=0) sot (spi=1) t cssi t cshi t csdi t d s e t csse t cshe t csde t dee
document number: 001 - 99224 rev.** page 88 of 115 s6e1b3 series preliminary uart external clock input (ext = 1 ) (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol conditions value unit remarks min max serial clock l pulse width t slsh c l = 30 pf t cycp + 10 - ns serial clock h pulse width t shsl t cycp + 10 - ns sck falling time t f - 5 ns sck rising time t r - 5 ns t shsl v i l v i l v i l v ih v ih t r t f t slsh s ck
document number: 001 - 99224 rev.** page 89 of 115 s6e1b3 series preliminary 11.4.10 external input timing (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions value unit remarks min max input pulse width t inh, t inl adtgx - 2 t cycp * 1 - ns a/d converter trigger input frckx free - run timer input clock icxx input capture dttixx - 2 t cycp * 1 - ns wave form generator int xx , nmix *2 2 t cycp + 100 * 1 - ns external interrupt , nmi *3 500 - ns wkupx *4 500 - ns deep standby wake up *1: t cycp represents the apb bus clock cycle time . for the number of the apb bus to which the multi - function timer is connected and that of the apb bus to which the external interrupt controller is connected, see " 8 . block diagram ". * 2 : in run mode and sleep mode * 3 : in timer mode and rtc mode and stop mode * 4 : in deep standby rtc mode and deep standby stop mode
document number: 001 - 99224 rev.** page 90 of 115 s6e1b3 series preliminary 11.4.11 i 2 c timing (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol conditions standard - mode fast - mode unit remarks min max min max scl clock frequency f scl c l = 30 pf, r = (v p /i ol ) * 1 0 100 0 400 khz (repeated) start condition hold time sda scl hdsta 4.0 - 0.6 - scl clock l width t low 4.7 - 1.3 - scl clock h width t high 4.0 - 0.6 - (repeated) start setup time scl sda susta 4.7 - 0.6 - data hold time scl sda hddat 0 3.45* 2 0 0.9* 3 data setup time sda scl sudat 250 - 100 - ns stop condition setup time scl sda susto 4.0 - 0.6 - bus free time between stop condition and start condition t buf 4.7 - 1.3 - noise filter t sp - 2 t cycp * 4 - 2 t cycp * 4 - ns *1: r represent s the pull - up resistance of the scl and sda lines , and c l the load capacitance of the scl and sda lines. v p represents the power supply voltage of the pull - up resistance , and i ol the v ol guaranteed current. *2: the maximum t hddat must satisfy at least the condition that the period during which the device is holding the scl signal at l (t low ) does not extend. *3: a fast - mode i 2 c bus device can be used in a s tandard - mode i 2 c bus system , provided that t he condition of t sudat 250 ns is fulfilled. *4: t cycp represents the apb bus clock cycle time. for the number of the apb bus to which the i 2 c is connected, see " 8 . block diagram ". to use s tandard - mode, set the apb bus clock at 2 mhz or more. to use fast - mode, set the apb bus clock at 8 mhz or more. s cl sda
document number: 001 - 99224 rev.** page 91 of 115 s6e1b3 series preliminary 11.4.12 i 2 s timing (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions v cc < 2.7 v v cc 2.7 v unit min max min max mi2sck max frequency (*1) f mi2sck mi2sck x c l = 30 pf - 6.144 - 6.144 m hz i 2 s clock cycle time (*1) t icyc mi2sck x 4 t cycp - 4 t cycp - ns i 2 s clock duty cycle ? swdt mi2sck x, mi2sws x - 30 +30 - 20 +20 ns mi2sck sddt mi2sck x, mi2sdo x - 30 +30 - 20 +20 ns mi2sdi dsst mi2sck x, mi2sdi x 50 - 3 6 - ns mi2sck sdht mi2sck x, mi2sdi x 0 - 0 - ns mi2sck falling time tf mi2sck x - 5 - 5 ns mi2sck rising time tr mi2sck x - 5 - 5 ns *1: i 2 s clock should meet the multiple of pclk(t icyc ) and the frequency less than f mi2sck meantime . the detail information p lease refer to chapter i 2 s of communication macro part of peripheral manual . m i 2 s c k m i 2 s w s a n d m i 2 s d o m i 2 s d i v i l v o h v o l v i h v i l v i h v i l v i h v i l v i h t f t r t s w d t , t s d d t t d s s t t s d h t
document number: 001 - 99224 rev.** page 92 of 115 s6e1b3 series preliminary 11.4.13 smart card interface ch aracteristics (v cc = a v cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions value unit remarks min max output rising time t r icx_ vcc , icx_rst , icx _clk , icx_data c l = 30 pf 4 20 ns output falling time t f 4 20 ns output clock frequency f clk icx _clk - 20 mhz duty cycle ? 45% 55% ? external pull - up resistor (20 k to 50 k ) must be applied to icx_cin pin when its used as smart card reader function.
document number: 001 - 99224 rev.** page 93 of 115 s6e1b3 series preliminary 11.4.14 sw - dp timing (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions value unit remarks min max swdio setup time t s ws sw c l k, swdio - 15 - ns swdio hold time t sw h sw c l k, swdio - 15 - ns swdio delay time t sw d swclk, swdio - - 45 ns note: ? external load capacitance c l = 30 pf swdio (when input) swclk swdio (when output) sw d
document number: 001 - 99224 rev.** page 94 of 115 s6e1b3 series preliminary 11.5 12 - bit a/d converter electrical characteristics of a/d c onverter ( preliminary values ) (v cc = av cc = 1.65 v to 3.6 v, v ss = av ss = 0 v, t a = - 40c to + 10 5 c) parameter symbol pin name value unit remarks min typ max resolution - - - - 12 bit integral nonl inearity - - - 4.5 - 4.5 lsb differential non linearity - - - 2.5 - + 2.5 lsb zero transition voltage v z t an xx - 15 - + 15 mv full - scale transition voltage v fst an xx avrh - 15 - avrh + 15 mv conversion time * 1 - - 2 . 0 - - cc cc < 2.7 v 10 - - 1.65 cc < 1.8 v sampling time * 2 t s - 0.6 - 10 cc cc < 2.7 v 3.0 - 1.65 cc < 1.8 v compare clock cycle * 3 t cck - 100 - 1000 ns a v cc cc < 2.7 v 500 - 1.65 cc < 1.8 v state transition time to operation permission t stt - - - 1.0 ain - - - 9.7 pf analog input resistance r ain - - - 2. 2 k cc cc < 2.7 v 10.5 1.65 cc < 1.8 v interchannel disparity - - - - 4 lsb analog port input leak current - an xx - - 5 ss - avrh v reference voltage - avrh 2.7 - a v cc v avcc 2.7v cc avcc < 2.7v *1: the c onversion time is the value of sampling time ( t s ) + compare time ( t c ). the minimum conversion time is computed according to the following conditions: a v cc 2 . 7 v sampling time = 0.6 s , compare time = 1.4 s 1.8 a v cc < 2.7 v sampling time = 1.2 s , compare time = 2.8 s 1.65 a v cc < 1.8 v sampling time = 3.0 s , compare time = 7.0 s ensure that the conversion time satisfies the specifications of the sampling time ( t s ) and compare clock cycle ( t cck ). for details of the settings of the sampling time and compare clock cycle, refer to " chapter : a/d converter " in " fm0+ family peripheral manual analog macro part ". the register setting s of the a / d c onverter are reflected in the operation according to the apb bus clock timing. for the number of the apb bus to which the a/d converter is connected, see " 8 . block diagram ". the base clock (hclk) is used to generate the sampling time and the compare clock cyc le. *2: the required sampling time varies according to the external impedance. set a sampling time that satisfies ( equation 1 ). *3: the compare time ( t c ) is the result of ( equation 2).
document number: 001 - 99224 rev.** page 95 of 115 s6e1b3 series preliminary (equation 1) t s ( r ain + r ext ) c ain 9 t s : sampling time r ai n : i nput resistance of a/d converter = 2.2 k with 2.7 < a v cc < 3.6 ch. 1 to ch. 14, ch. 16 to ch. 19 i nput resistance of a/d converter = 1.9 k with 2.7 < a v cc < 3.6 ch. 15 i nput resistance of a/d converter = 2.3 k with 2.7 < a v cc < 3.6 ch. 20 to ch. 23 i nput resistance of a/d converter = 5.7 k with 1.8 < a v cc < 2.7 ch. 1 to ch. 14, ch. 16 to ch. 19 i nput resistance of a/d converter = 5.6 k with 1.8 < a v cc < 2.7 ch. 15 i nput resistance of a/d converter = 5.8 k with 1.8 < a v cc < 2.7 ch. 20 to ch. 23 i nput resistance of a/d converter = 12.6 k with 1.65 < a v cc < 1.8 ch. 1 to ch. 19 i nput resistance of a/d converter = 12.7 k with 1.65 < a v cc < 1.8 ch. 20 to ch. 23 c ain : i nput capacit ance of a/d converter = 9.7 pf with 2.7 < a v cc < 3.6 r ext : output impedance of external circuit (equation 2) t c = t cck 14 t c : compare time t cck : compare clock cycle r ext r ain c omparator an xx analog input pin s c ain analog signal source
document number: 001 - 99224 rev.** page 96 of 115 s6e1b3 series preliminary definition s of 1 2 - bit a/d converter terms ? resolution : analog variation that is recognized by an a/d converter. ? integral nonl inearity : deviation of the line between the zero - transition point (0b000000000000 0b000000000001) and the full - scale transition point (0b111111111110 0b111111111111) from the actual conversion characteristics. ? differential non linearity : deviation from the ideal value of the input voltage that is required to change the output code by 1 lsb. integral nonl inearity of digital output n = v nt - {1lsb (n - 1) + v z t } [lsb] 1lsb differential nonlinearity of digital output n = v (n + 1) t - v nt - 1 [lsb] 1lsb 1lsb = v fst C z t 4094 n : a/d converter digital output value. v z t : voltage at whi ch the digital output ch anges from 0x000 to 0x001. v fst : voltage at whi ch the digital output ch anges from 0xffe to 0xfff. v nt : voltage at whi ch the digital output ch anges from 0x(n ? 1) to 0xn. integral nonl inearity differential non linearity digital output digital output actual conversion characteristics actual conversion characteristics ideal characteristics (actually - measured value) actual conversion characteristics actual conversion characteristics (actually - measured value) (actually - measured value) ideal characteristics (actually - measured value) analog input analog input (actually - measured value) 0x001 0x002 0x003 0x004 0x f fd 0x f fe 0x f ff av ss avrh av ss avrh 0x(n - 2) 0x(n - 1) 0x(n+1) 0xn {1 lsb(n - 1) + v zt } v nt v fst v zt v nt v (n+1)t
document number: 001 - 99224 rev.** page 97 of 115 s6e1b3 series preliminary 11.6 usb ch aracteri stics ( v cc = 3.0 v to 3.6 v, v ss = 0 v, t a = - 40 c to + 10 5 c ) parameter symbol pin name conditions value unit remarks min max input characteristics input h level voltage v ih udp0, udm0 - 2.0 v cc + 0.3 v *1 input l level voltage v il - v ss C 0.3 0.8 v *1 differential input sensitivity v di - 0.2 - v *2 differential common mode range v cm - 0.8 2.5 v *2 output characteristic output h level voltage v oh external pull - down resistance = 15 k? 2.8 3.6 v *3 output l level voltage v ol external pull - up resistance = 1.5 k? 0.0 0.3 v *3 crossover voltage v crs - 1.3 2.0 v *4 rising time t fr full - speed 4 20 ns *5 falling time t ff full - speed 4 20 ns *5 rising/falling time matching t frfm full - speed 90 111.11 % *5 output impedance z drv full - speed 28 44 ? *6 rising time t lr low - speed 75 300 ns *7 falling time t lf low - speed 75 300 ns *7 rising/falling time matching t lrfm low - speed 80 125 % *7 *1 : the switching threshold voltage of single - end - receiver of usb i/o buffer is set as within v il (max) = 0.8 v, vih(min) = 2.0 v (ttl input standard). there are some hysteresis to lower noise sensitivity. *2 : use differential - receiver to receive usb differential data signal. differential - receiver has 200 mv of differential input sensitivity w hen the differential data input is within 0.8 v to 2.5 v to the local ground reference level. above voltage range is the common mode input voltage range. 0.8 2.5 common mode input voltage [v] minimum differential input sensitivity [v] 0. 2 1.0
document number: 001 - 99224 rev.** page 98 of 115 s6e1b3 series preliminary *3 : the output drive capability of the driver is below 0.3 v at low - state (v ol ) (to 3.6 v and 1.5 k? load), and 2.8 v or above (to the vss and 1.5 k? load) at high - state (v oh ) *4 : the cross voltage of the external differential output signal (d+ / d - ) of usb i/o buffer is within 1.3 v to 2.0 v. *5 : the indicate rising time (trise) and falling time (tfall) of the full - speed differential data signal. they are defined by the time between 10% and 90% of the output signal voltage. for full - speed buffer, tr/tf ratio is regulated as within 10% to minimize rfi emission. *6 : usb full - speed connection is performed via twist pair cable shield with 90 ? 15% characteristic impedance (differential mode). usb standard defines that output impedance of usb driver must be in range from 28? to 44?. so, discrete series resistor (rs) addition is defined in order to satisfy the above definition and keep balance. when using this usb i/o, use it with 25 ? to 33 ? (recommendation value : 27 ?) series resistor rs. v crs specified range max 2.0v d+ min 1.3v d - trise rising time 90% d+ d - 10% 90% 10% tfall falling time tx d + tx d - rs=27 ? rs=27 ? c l =50 pf c l =50 pf full - speed buffer 3 - state enable
document number: 001 - 99224 rev.** page 99 of 115 s6e1b3 series preliminary *7 : they indicate rising time (trise) and falling time (tfall) of the low - speed differential data signal. they are defined by the time between 10% and 90% of the output signal voltage. see low - speed load (com p liance load) for condition of external load. tx d + tx d - rs rs full - speed buffer 3 - state enable 28 ? to 44 ? equivalent impedance 28 ? to 44 ? equivalent impedance rs series resistor 25 ? to 30 ? series resistor of 27 ? (recommendation value) must be added. and, use resistance with an uncertainty of 5% by e24 sequence. 90% d+ d - 10% 90% 10% tfall falling time
document number: 001 - 99224 rev.** page 100 of 115 s6e1b3 series preliminary ? low - speed load (upstream port load) C reference 1 ? low - speed load (downstream port load) C reference 2 tx d + tx d - rs=27 ? rs=27 ? c l =50 pf to 150 pf low - speed buffer 3 - state enable rpd c l =50 pf to 150 pf rpd rpd=15 k? tx d + tx d - rs=27 ? rs=27 ? c l =200 pf to 600 pf low - speed buffer 3 - state enable c l =50 pf to 150 pf rpu=1.5 k? vterm=3.6 v vterm
document number: 001 - 99224 rev.** page 101 of 115 s6e1b3 series preliminary ? low - speed load (compliance load) tx d + tx d - rs=27 ? rs=27 ? c l =200 pf to 450 pf low - speed buffer 3 - state enable c l =200 pf to 450 pf
document number: 001 - 99224 rev.** page 102 of 115 s6e1b3 series preliminary 11.7 low - voltage d etection ch aracteristics 11.7.1 l ow - voltage d etection r eset ( t a = - 40 c to + 10 5 c ) parameter symbol conditions value unit remarks min typ max detected voltage vdl fixed *1 1.38 1.50 1.60 v when voltage drops released voltage vdh 1.43 1.55 1.65 v when voltage rises lvd stabilization wait time t lvdw - - - 8160 t cycp *2 lvd dl - - - 200 cycp indicates the apb 1 bus clock cycle time.
document number: 001 - 99224 rev.** page 103 of 115 s6e1b3 series preliminary 11.7.2 l ow - voltage d etection interrupt ( t a = - 40 c to + 10 5 c ) parameter symbol conditions value unit remarks min typ max detected voltage vdl svhi = 00100 1.56 1.70 1.84 v when voltage drops released voltage vdh svhrli = 00100 1.61 1.75 1.89 v when voltage rises detected voltage vdl svhi = 00101 1.61 1.75 1.89 v when voltage drops released voltage vdh svhrli = 00101 1.66 1.80 1.94 v when voltage rises detected voltage vdl svhi = 00110 1.66 1.80 1.94 v when voltage drops released voltage vdh svhrli = 00110 1.70 1.85 2.00 v when voltage rises detected voltage vdl svhi = 00111 1.70 1.85 2.00 v when voltage drops released voltage vdh svhrli = 00111 1.75 1.90 2.05 v when voltage rises detected voltage vdl svhi = 01000 1.75 1.90 2.05 v when voltage drops released voltage vdh svhrli = 01000 1.79 1.95 2.11 v when voltage rises detected voltage vdl svhi = 01001 1.79 1.95 2.11 v when voltage drops released voltage vdh svhrli = 01001 1.84 2.00 2.16 v when voltage rises detected voltage vdl svhi = 01010 1.84 2.00 2.16 v when voltage drops released voltage vdh svhrli = 01010 1.89 2.05 2.21 v when voltage rises detected voltage vdl svhi = 01011 1.89 2.05 2.21 v when voltage drops released voltage vdh svhrli = 01011 1.93 2.10 2.27 v when voltage rises detected voltage vdl svhi = 01100 2.30 2.50 2.70 v when voltage drops released voltage vdh svhrli = 01100 2.39 2.60 2.81 v when voltage rises detected voltage vdl svhi = 01101 2.39 2.60 2.81 v when voltage drops released voltage vdh svhrli = 01101 2.48 2.70 2.92 v when voltage rises detected voltage vdl svhi = 01110 2.48 2.70 2.92 v when voltage drops released voltage vdh svhrli = 01110 2.58 2.80 3.02 v when voltage rises detected voltage vdl svhi = 01111 2.58 2.80 3.02 v when voltage drops released voltage vdh svhrli = 01111 2.67 2.90 3.13 v when voltage rises detected voltage vdl svhi = 10000 2.67 2.90 3.13 v when voltage drops released voltage vdh svhrli = 10000 2.76 3.00 3.24 v when voltage rises detected voltage vdl svhi = 10001 2.76 3.00 3.24 v when voltage drops released voltage vdh svhrli = 10001 2.85 3.10 3.35 v when voltage rises detected voltage vdl svhi = 10010 2.85 3.10 3.35 v when voltage drops released voltage vdh svhrli = 10010 2.94 3.20 3.46 v when voltage rises detected voltage vdl svhi = 10011 2.94 3.20 3.46 v when voltage drops released voltage vdh svhrli = 10011 3.04 3.30 3.56 v when voltage rises lvd stabilization wait time t lvdw - - - 8160 t cycp * lvd dl - - - 200 *:t cycp represents the apb 1 bus clock cycle time.
document number: 001 - 99224 rev.** page 104 of 115 s6e1b3 series preliminary 11.7.3 l ow - voltage d etection interrupt 2 ( t a = - 40 c to + 10 5 c ) parameter symbol conditions value unit remarks min typ max detected voltage vdl svh2i = 00100 1.56 1.70 1.84 v when voltage drops released voltage vdh svh2rli = 00100 1.61 1.75 1.89 v when voltage rises detected voltage vdl svh2i = 00101 1.61 1.75 1.89 v when voltage drops released voltage vdh svh2rli = 00101 1.66 1.80 1.94 v when voltage rises detected voltage vdl svh2i = 00110 1.66 1.80 1.94 v when voltage drops released voltage vdh svh2rli = 00110 1.70 1.85 2.00 v when voltage rises detected voltage vdl svh2i = 00111 1.70 1.85 2.00 v when voltage drops released voltage vdh svh2rli = 00111 1.75 1.90 2.05 v when voltage rises detected voltage vdl svh2i = 01000 1.75 1.90 2.05 v when voltage drops released voltage vdh svh2rli = 01000 1.79 1.95 2.11 v when voltage rises detected voltage vdl svh2i = 01001 1.79 1.95 2.11 v when voltage drops released voltage vdh svh2rli = 01001 1.84 2.00 2.16 v when voltage rises detected voltage vdl svh2i = 01010 1.84 2.00 2.16 v when voltage drops released voltage vdh svh2rli = 01010 1.89 2.05 2.21 v when voltage rises detected voltage vdl svh2i = 01011 1.89 2.05 2.21 v when voltage drops released voltage vdh svh2rli = 01011 1.93 2.10 2.27 v when voltage rises detected voltage vdl svh2i = 01100 2.30 2.50 2.70 v when voltage drops released voltage vdh svh2rli = 01100 2.39 2.60 2.81 v when voltage rises detected voltage vdl svh2i = 01101 2.39 2.60 2.81 v when voltage drops released voltage vdh svh2rli = 01101 2.48 2.70 2.92 v when voltage rises detected voltage vdl svh2i = 01110 2.48 2.70 2.92 v when voltage drops released voltage vdh svh2rli = 01110 2.58 2.80 3.02 v when voltage rises detected voltage vdl svh2i = 01111 2.58 2.80 3.02 v when voltage drops released voltage vdh svh2rli = 01111 2.67 2.90 3.13 v when voltage rises detected voltage vdl svh2i = 10000 2.67 2.90 3.13 v when voltage drops released voltage vdh svh2rli = 10000 2.76 3.00 3.24 v when voltage rises detected voltage vdl svh2i = 10001 2.76 3.00 3.24 v when voltage drops released voltage vdh svh2rli = 10001 2.85 3.10 3.35 v when voltage rises detected voltage vdl svh2i = 10010 2.85 3.10 3.35 v when voltage drops released voltage vdh svh2rli = 10010 2.94 3.20 3.46 v when voltage rises detected voltage vdl svh2i = 10011 2.94 3.20 3.46 v when voltage drops released voltage vdh svh2rli = 10011 3.04 3.30 3.56 v when voltage rises lvd stabilization wait time t lvdw - - - 8160 t cycp * lvd dl - - - 200 *:t cycp represents the apb 1 bus clock cycle time.
document number: 001 - 99224 rev.** page 105 of 115 s6e1b3 series preliminary 11.8 flash memory write/erase characteristics ( v cc = 1.65 v to 3.6 v , t a = - 40 c to + 10 5 c ) parameter value unit remarks min typ * max * sector erase time large s ector - 1.1 2.7 s the sector erase time includes the time of writing prior to internal erase. small sector - 0. 3 0.9 half word (16 - bit) write time - 30 528 w rite / erase cycle and data hold time ( target value ) w rite / erase cycle data hold time ( year ) remarks 1,000 20* 10,000 10* *: at average + 85 ? c
document number: 001 - 99224 rev.** page 106 of 115 s6e1b3 series preliminary 11.9 return time from low - power consumption mode 11.9.1 return f actor: interrupt/wkup the return time from low - power consumption mode is indicated as follows. it is from receiving the return factor to starting the program operation. return c ount t ime ( v cc = 1.65 v to 3.6 v , t a = - 40 c to + 10 5 c ) parameter symbol value unit remar ks typ max *1 sleep mode t icnt 6*hclk 7*hclk (*3) 38 + t oscwt (*2* 4) 71 71 + t oscwt (* 2*4) oscw t : oscillator stabilization time. *3: it is for hcr mode. *4: for clock mode except hcr mode. operation example of return from l ow - p ower consumption mode (by external interrupt *) *: external interrupt is set to detecting fall edge. e x t e r n a l i n t e r r u p t t i c n t i n t e r r u p t f a c t o r a c c e p t c p u o p e r a t i o n s t a r t a c t i v e i n t e r r u p t f a c t o r c l e a r b y c p u
document number: 001 - 99224 rev.** page 107 of 115 s6e1b3 series preliminary operation example of return from low - power consumption mode (by internal resource interrupt *) *: internal resource interrupt is not included in return factor by the kind of low - power consumption mode. notes: ? the return factor is different in each low - power consumption modes. see "chapter: low power consumption mode" and "operations of standby modes" in fm0+ family peripheral manual . ? when interrupt recoveries, the operation mode that cpu recoveries depends on the state before the low - power consumption mode transition. see " chapter : low power consumption mode" in "fm0+ family peripheral manual ". i n t e r n a l r e s o u r c e i n t e r r u p t t i c n t i n t e r r u p t f a c t o r a c c e p t c p u o p e r a t i o n s t a r t a c t i v e i n t e r r u p t f a c t o r c l e a r b y c p u
document number: 001 - 99224 rev.** page 108 of 115 s6e1b3 series preliminary 11.9.2 return f actor: reset the return time from low - power consumption mode is indicated as follows. it is from releasing reset to starting the program operation. return c ount t ime ( v cc = 1.65 v to 3.6 v , t a = - 40 c to + 10 5 c ) parameter symbol value unit remarks typ max* sleep mode t rcnt 10 *1 40 *2 70 *1 : hcr on.(hcr/mosc/pll mode) *2 : hcr off.(lcr/sos mode) high - speed cr timer mode, main timer mode, pll timer mode 20 30 low - speed cr timer mode 61 114 sub timer mode 61 114 rtc/stop mode 38 85 deep rtc mode, deep stop mode 46 95 *: the maximum value depends on the accuracy of built - in cr. operation example of return from l ow - p ower consumption mode (by initx) i n i t x t r c n t i n t e r n a l r e s e t c p u o p e r a t i o n s t a r t r e s e t a c t i v e r e l e a s e
document number: 001 - 99224 rev.** page 109 of 115 s6e1b3 series preliminary operation example of return from low power consumption mode (by internal resource reset *) *: internal resource reset is not included in return factor by the kind of low - power consumption mode. notes: ? the return factor is different in each low - power consumption modes. see "chapter: low power consumption mode" and "operations of standby modes" in fm0+ fami ly peripheral manual . ? when interrupt recoveries, the operation mode that cpu recoveries depends on the state before the low - power consumption mode transition. see " chapter : low power consumption mode" in "fm0+ family peripheral manual ". ? the time during the power - on reset/low - voltage det ection reset is excluded. see " 11.4.7 power - on reset timing in 11.4 ac characteristics in 11 . electrical characteristics " for the detail on the time during the power - on reset/low - voltage detection reset. ? when in recovery from reset, cpu changes to the high - speed cr run mode. when using the main clock or the pll clock, it is necessary to add the main clock oscillation stabilization wait time or the main pll clock stabilization wait time. ? the internal resource reset means the watchdog reset and the csv reset. i n t e r n a l r e s o u r c e r e s e t t r c n t i n t e r n a l r e s e t c p u o p e r a t i o n s t a r t r e s e t a c t i v e r e l e a s e
document number: 001 - 99224 rev.** page 110 of 115 s6e1b3 series preliminary 12. ordering information part number on - chip flash memory on - chip sram package packing s6e1b34e 0agv20000 304 32 plastic ? lqfp (0.5 0 mm pitch) , 80 pin s (fpt - 80 p - m 21 ) tray s6e1b36e 0agv20000 560 64 s6e1b34 f0agv20000 304 32 plastic ? lqfp (0.5 0 mm pitch) , 100 pin s (fpt - 100 p - m 20 ) tray s6e1b36 f0agv20000 560 64 s6e1b34g 0agv20000 304 32 plastic ? l qfp (0. 50 mm pitch) , 120 pin s ( fpt - 120 p - m 21 ) tray s6e1b36g 0agv20000 560 64
document number: 001 - 99224 rev.** page 111 of 115 s6e1b3 series preliminary 13. package dimensions
document number: 001 - 99224 rev.** page 112 of 115 s6e1b3 series preliminary
document number: 001 - 99224 rev.** page 113 of 115 s6e1b3 series preliminary
document number: 001 - 99224 rev.** page 114 of 115 s6e1b3 series preliminary document history document title: s6e1b3 series 32 - bit arm ? cortex ? - m0+ fm0+ microcontroller document number: 001 - 99224 revision ecn orig. of change submission date description of change ** 4889752 t e k a 0 8 / 31 /2015 new spec.
docume nt number: 001 - 99224 rev.** august 31, 2015 page 115 of 115 s6e1b3 series preliminary sales, solutions, and legal information worldwide sales and design support cypress maintains a worldwide network of offices, solution centers, manufacturers representatives, and distributors. to find the office closest to you, visit us at cypress locations . products automotive cypress.com/go/automotive clocks & buffers cypress.com/go/clocks interface cypress.com/go/interface lighting & pow er control cypress.com/go/powerpsoc memory cypress.com/go/memory psoc cypress.com/go/psoc touch sensing cypress.com/go/touch usb controllers cypress.com/go/usb wireless/rf cypress.com/go/wireless spansion products spansion.com/ p roducts psoc? solutions psoc.cypress.com/solutions psoc 1 | psoc 3 | psoc 4 | psoc 5lp cypress developer community community | forums | blogs | video | training technical support cypress.com/go/support cypress, the cypress logo, spansion ? , the spansion logo, mirrorbit ? , mirrorbit ? eclipse tm , ornand tm , easy designsim tm , traveo tm and combinations thereof, are trademarks and registered trademarks of cypress semiconductor corp. arm and cortex are the registered trademarks of arm limited in the eu and other countries. all other trademarks or registered trademarks referenced herein ar e the property of their respective owners. ? cypress semiconductor corporation, 201 5 . the information contained herein is subject to change without notice. cypress semiconductor corporation assumes no responsi bility for the use of any circuitry other th an circuitry embodied in a cypress product. nor does it convey or imply any license under patent or other rights. cypress pro ducts are not warranted nor intended to be used for medical, life support, life saving, critical control or safety applications, un less pursuant to an express written agreement with cypress. furthermore, cypress does not authorize its products for use as critical components in life - support systems where a malfunction or failure may reasonably be expected to result in significant injur y to the user. the inclusion of cypress products in life - support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies cypress against al l charges. this source code (software and/or firmware) is owned b y cypress semiconductor corporation (cypress) and is protected by and subject to worldwide patent protection (united states a nd foreign), united states copyright laws and international treaty provisions. cypress hereby grants to licensee a personal, non - ex clusive, non - transferable license to copy, use, modify, create derivative works of, and compile the cypress source code and derivative works for the sole purpose of creating custom software and or firmware in support of licensee product to be used only in conjunction with a cypress integrated circuit as specified in the applicable agreement. any reproduction, modification, translation, compilation , or representation of this source code except as specified above is prohibited without the express written perm ission of cypress. disclaimer: cypress makes no warranty of any kind, express or implied, with regard to this material, including, but not limit ed to, the implied warranties of merchantability and fitness for a particular purpose. cypress reserves the righ t to make changes without further notice to the materials described herein. cypress does not assume any liability arising out of the application or use of any product or circuit described herein. cypress does not autho rize its products for use as critical components in life - support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. the inclusion of cypress pr oduct in a life - support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies cypress against all charges. use may be limited by and subject to the applicable cypress software license agreement.

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