|
If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
Datasheet File OCR Text: |
PROFET(R) BTS 712 N1 Smart Four Channel Highside Power Switch Features * Overload protection * Current limitation * Short-circuit protection * Thermal shutdown * Overvoltage protection (including load dump) * Fast demagnetization of inductive loads * Reverse battery protection1) * Undervoltage and overvoltage shutdown with auto-restart and hysteresis * Open drain diagnostic output * Open load detection in OFF-state * CMOS compatible input * Loss of ground and loss of Vbb protection * Electrostatic discharge (ESD) protection Product Summary Overvoltage Protection Operating voltage active channels: On-state resistance RON Nominal load current IL(NOM) Current limitation IL(SCr) Vbb(AZ) 43 V Vbb(on) 5.0 ... 34 V two parallel four parallel one 200 100 50 m 1.9 2.8 4.4 A 4 4 4 A Application * C compatible power switch with diagnostic feedback for 12 V and 24 V DC grounded loads * All types of resistive, inductive and capacitive loads * Replaces electromechanical relays and discrete circuits General Description N channel vertical power FET with charge pump, ground referenced CMOS compatible input and diagnostic feedback, monolithically integrated in Smart SIPMOS(R) technology. Fully protected by embedded protection functions. Pin Definitions and Functions Pin 1,10, 11,12, 15,16, 19,20 3 5 7 9 18 17 14 13 4 8 2 6 Symbol Function Positive power supply voltage. Design the Vbb wiring for the simultaneous max. short circuit currents from channel 1 to 4 and also for low thermal resistance IN1 Input 1 .. 4, activates channel 1 .. 4 in case of IN2 logic high signal IN3 IN4 OUT1 Output 1 .. 4, protected high-side power output OUT2 of channel 1 .. 4. Design the wiring for the OUT3 max. short circuit current OUT4 ST1/2 Diagnostic feedback 1/2 of channel 1 and channel 2, open drain, low on failure ST3/4 Diagnostic feedback 3/4 of channel 3 and channel 4, open drain, low on failure GND1/2 Ground 1/2 of chip 1 (channel 1 and channel 2) GND3/4 Ground 3/4 of chip 2 (channel 3 and channel 4) Pin configuration (top view) Vbb GND1/2 IN1 ST1/2 IN2 GND3/4 IN3 ST3/4 IN4 Vbb 1 2 3 4 5 6 7 8 9 10 * 20 19 18 17 16 15 14 13 12 11 Vbb Vbb OUT1 OUT2 Vbb Vbb OUT3 OUT4 Vbb Vbb 1) With external current limit (e.g. resistor RGND=150 ) in GND connection, resistor in series with ST connection, reverse load current limited by connected load. Semiconductor Group 1 06.96 BTS 712 N1 Block diagram Four Channels; Open Load detection in off state; Voltage source Overvoltage protection Current limit 1 Gate 1 protection Channel 1 + V bb Leadframe V Logic Voltage sensor Level shifter Rectifier 1 Charge pump 1 Charge pump 2 Limit for unclamped ind. loads 1 Open load Short to Vbb detection 1 Current limit 2 Gate 2 protection Channel 2 OUT1 18 3 5 4 IN1 IN2 Temperature sensor 1 ESD ST1/2 Logic 2 GND1/2 Level shifter Rectifier 2 Limit for unclamped ind. loads 2 Open load Short to Vbb detection 2 OUT2 17 Load Temperature sensor 2 Signal GND Chip 1 Chip 1 Load GND + V bb Leadframe Logic and protection circuit of chip 2 (equivalent to chip 1) 7 9 8 IN3 IN4 ST3/4 Channel 3 OUT3 14 Channel 4 OUT4 13 Load 6 GND3/4 PROFET Signal GND Chip 2 (R) Load GND Chip 2 Leadframe connected to pin 1, 10, 11, 12, 15, 16, 19, 20 Maximum Ratings at Tj = 25C unless otherwise specified Parameter Supply voltage (overvoltage protection see page 4) Supply voltage for full short circuit protection Tj,start = -40 ...+150C Symbol Values 43 34 Unit V V Vbb Vbb Semiconductor Group 2 BTS 712 N1 Maximum Ratings at Tj = 25C unless otherwise specified Parameter Symbol Values Unit Load current (Short-circuit current, see page 5) Load dump protection2) VLoadDump = UA + Vs, UA = 13.5 V RI3) = 2 , td = 200 ms; IN = low or high, each channel loaded with RL = 7.1 , Operating temperature range Storage temperature range Power dissipation (DC)5 Ta = 25C: (all channels active) Ta = 85C: Inductive load switch-off energy dissipation, single pulse Vbb = 12V, Tj,start = 150C5), IL = 1.9 A, ZL = 66 mH, 0 one channel: IL = 2.8 A, ZL = 66 mH, 0 two parallel channels: IL = 4.4 A, ZL = 66 mH, 0 four parallel channels: see diagrams on page 9 IL VLoad dump4) Tj Tstg Ptot self-limited 60 -40 ...+150 -55 ...+150 3.6 1.9 A V C W EAS 150 320 800 1.0 -10 ... +16 2.0 5.0 mJ Electrostatic discharge capability (ESD) (Human Body Model) Input voltage (DC) Current through input pin (DC) Current through status pin (DC) see internal circuit diagram page 8 VESD VIN IIN IST kV V mA Thermal resistance junction - soldering point5),6) junction - ambient5) each channel: one channel active: all channels active: Rthjs Rthja 16 44 35 K/W 2) 3) 4) 5) 6) Supply voltages higher than Vbb(AZ) require an external current limit for the GND and status pins, e.g. with a 150 resistor in the GND connection and a 15 k resistor in series with the status pin. A resistor for input protection is integrated. RI = internal resistance of the load dump test pulse generator VLoad dump is setup without the DUT connected to the generator per ISO 7637-1 and DIN 40839 Device on 50mm*50mm*1.5mm epoxy PCB FR4 with 6cm2 (one layer, 70m thick) copper area for Vbb connection. PCB is vertical without blown air. See page 14 Soldering point: upper side of solder edge of device pin 15. See page 14 Semiconductor Group 3 BTS 712 N1 Electrical Characteristics Parameter and Conditions, each of the four channels at Tj = 25 C, Vbb = 12 V unless otherwise specified Symbol Values min typ max Unit Load Switching Capabilities and Characteristics On-state resistance (Vbb to OUT) Tj = 25C: RON IL = 1.8 A each channel, Tj = 150C: two parallel channels, Tj = 25C: four parallel channels, Tj = 25C: Nominal load current one channel active: two parallel channels active: four parallel channels active: 5), T = 85C, T 150C Device on PCB a j Output current while GND disconnected or pulled up; Vbb = 30 V, VIN = 0, see diagram page 9 Turn-on time to 90% VOUT: Turn-off time to 10% VOUT: RL = 12 , Tj =-40...+150C Slew rate on Tj =-40...+150C: 10 to 30% VOUT, RL = 12 , Slew rate off Tj =-40...+150C: 70 to 40% VOUT, RL = 12 , Operating Parameters Operating voltage7) Undervoltage shutdown Undervoltage restart -- 165 320 83 42 1.9 2.8 4.4 -200 200 --- 200 400 100 50 -- m IL(NOM) 1.7 2.6 4.1 -80 80 0.1 0.1 A IL(GNDhigh) ton toff dV/dton -dV/dtoff 10 400 400 1 1 mA s V/s V/s Tj =-40...+150C: Tj =-40...+150C: Tj =-40...+25C: Tj =+150C: Undervoltage restart of charge pump Tj =-40...+150C: see diagram page 13 Undervoltage hysteresis Vbb(under) = Vbb(u rst) - Vbb(under) Tj =-40...+150C: Overvoltage shutdown Tj =-40...+150C: Overvoltage restart Tj =-40...+150C: Overvoltage hysteresis 8) Tj =-40...+150C: Overvoltage protection I bb = 40 mA Vbb(on) Vbb(under) Vbb(u rst) Vbb(ucp) Vbb(under) 5.0 3.5 ---34 33 -42 ---5.6 0.2 --0.5 47 34 5.0 5.0 7.0 7.0 -43 ---- V V V V V V V V V Vbb(over) Vbb(o rst) Vbb(over) Vbb(AZ) 7) 8) At supply voltage increase up to Vbb = 5.6 V typ without charge pump, VOUT Vbb - 2 V see also VON(CL) in circuit diagram on page 8. Semiconductor Group 4 BTS 712 N1 Parameter and Conditions, each of the four channels at Tj = 25 C, Vbb = 12 V unless otherwise specified Symbol Values min typ max ----180 160 0.35 1.2 300 300 0.8 2.8 Unit A Standby current, all channels off Tj =25C: Ibb(off) VIN = 0 Tj =150C: 9), V = 5V, Operating current IN Tj =-40...+150C IGND = IGND1/2 + IGND3/4, one channel on: IGND four channels on: Protection Functions Initial peak short circuit current limit, (see timing diagrams, page 11) mA each channel, Tj =-40C: IL(SCp) 5.5 9.5 13 4.5 7.5 11 Tj =25C: 2.5 4.5 7 Tj =+150C: two parallel channels twice the current of one channel four parallel channels four times the current of one channel Repetitive short circuit current limit, Tj = Tjt each channel IL(SCr) -4 --4 -two parallel channels -4 -four parallel channels (see timing diagrams, page 11) A A Initial short circuit shutdown time Tj,start =-40C: toff(SC) Tj,start = 25C: VON(CL) Tjt Tjt ---150 -- 5.5 4 47 -10 ------ ms (see page 10 and timing diagrams on page 11) Output clamp (inductive load switch off)10) at VON(CL) = Vbb - VOUT Thermal overload trip temperature Thermal hysteresis Reverse Battery Reverse battery voltage 11) Drain-source diode voltage (Vout > Vbb) IL = - 1.9 A, Tj = +150C Diagnostic Characteristics Open load detection current Open load detection voltage V C K -Vbb -VON --- -610 32 -- V mV IL(off) Tj =-40..+150C: VOUT(OL) -2 30 3 -4 A V 9) 10) Add IST, if IST > 0 If channels are connected in parallel, output clamp is usually accomplished by the channel with the lowest VON(CL) 11) Requires a 150 resistor in GND connection. The reverse load current through the intrinsic drain-source diode has to be limited by the connected load. Note that the power dissipation is higher compared to normal operating conditions due to the voltage drop across the intrinsic drain-source diode. The temperature protection is not active during reverse current operation! Input and Status currents have to be limited (see max. ratings page 3 and circuit page 8). Semiconductor Group 5 BTS 712 N1 Parameter and Conditions, each of the four channels at Tj = 25 C, Vbb = 12 V unless otherwise specified Symbol Values min typ max Unit Input and Status Feedback12) Input resistance (see circuit page 8) Tj =-40..+150C: Tj =-40..+150C: RI VIN(T+) VIN(T-) 2.5 1.7 1.5 -1 20 -- 3.5 --0.5 -50 220 6 3.5 --50 90 -- k V V V A A s Input turn-on threshold voltage Input turn-off threshold voltage Tj =-40..+150C: Input threshold hysteresis Off state input current Tj =-40..+150C: On state input current Tj =-40..+150C: Delay time for status with open load (see timing diagrams, page 12) VIN(T) VIN = 0.4 V: IIN(off) VIN = 5 V: IIN(on) td(ST OL3) Status output (open drain) Zener limit voltage Tj =-40...+150C, IST = +1.6 mA: VST(high) ST low voltage Tj =-40...+25C, IST = +1.6 mA: VST(low) Tj = +150C, IST = +1.6 mA: 5.4 --- 6.1 --- -0.4 0.6 V 12) If ground resistors RGND are used, add the voltage drop across these resistors. Semiconductor Group 6 BTS 712 N1 Truth Table Channel 1 and 2 Channel 3 and 4 (equivalent to channel 1 and 2) Normal operation Chip 1 Chip 2 IN1 IN3 IN2 IN4 OUT1 OUT3 OUT2 OUT4 ST1/2 ST3/4 BTS 711L1 H H H H H(L13)) H L H(L13)) H L L14) H H(L15)) L14) H H(L15)) H L L H L H L H ST1/2 ST3/4 BTS 712N1 H H H H L H H L H H L14) H H L14) H H H L L H L H L H Open load Channel 1 (3) Channel 2 (4) Short circuit to Vbb Channel 1 (3) Channel 2 (4) Overtemperature both channel Channel 1 (3) Channel 2 (4) Undervoltage/ Overvoltage L L H H L L H L H X L L H L H X L X H L H X X X L H L H L H X L L H L H X L L H L H X X X L H X L L H H Z Z H L H X H H H L H X L L L L L X X L L H L H L H X Z Z H L H X H H H L L L X X L L L L = "Low" Level H = "High" Level X = don't care Z = high impedance, potential depends on external circuit Status signal valid after the time delay shown in the timing diagrams Parallel switching of channel 1 and 2 (also channel 3 and 4) is easily possible by connecting the inputs and outputs in parallel (see truth table). If switching channel 1 to 4 in parallel, the status outputs ST1/2 and ST3/4 have to be configured as a 'Wired OR' function with a single pull-up resistor. Terms V Ibb bb Leadframe I IN1 I IN2 I ST1/2 V IN1 VIN2 VST1/2 3 5 4 IN1 IN2 Vbb OUT1 PROFET Chip 1 18 V ON1 V ON2 I L1 I IN4 I L2 V OUT1 I GND1/2 R GND1/2 VOUT2 R GND3/4 I ST3/4 V IN3 VIN4 VST3/4 Leadframe I IN3 7 9 8 IN3 IN4 Vbb OUT3 PROFET Chip 2 14 VON3 V ON4 I L3 I L4 V OUT3 IGND3/4 VOUT4 OUT2 17 OUT4 13 ST1/2 GND1/2 2 ST3/4 GND3/4 6 Leadframe (Vbb) is connected to pin 1,10,11,12,15,16,19,20 External RGND optional; two resistors RGND1/2 ,RGND3/4 = 150 or a single resistor RGND = 75 for reverse battery protection up to the max. operating voltage. 13) 14) With additional external pull up resistor An external short of output to Vbb in the off state causes an internal current from output to ground. If R GND is used, an offset voltage at the GND and ST pins will occur and the VST low signal may be errorious. 15) Low resistance to V may be detected by no-load-detection bb Semiconductor Group 7 BTS 712 N1 Input circuit (ESD protection), IN1...4 R IN I RI Logic V Z2 Overvoltage protection of logic part GND1/2 or GND3/4 + V bb ESD-ZD I GND IN I I IN R ST ST ESD zener diodes are not to be used as voltage clamp at DC conditions. Operation in this mode may result in a drift of the zener voltage (increase of up to 1 V). V Z1 GND R GND Status output, ST1/2 or ST3/4 +5V Signal GND VZ1 = 6.1 V typ., VZ2 = 47 V typ., RI = 3.5 k typ., RGND = 150 R ST(ON) ST Reverse battery protection + 5V - Vbb GND ESDZD R ST IN ST ESD-Zener diode: 6.1 V typ., max 5.0 mA; RST(ON) < 380 at 1.6 mA, ESD zener diodes are not to be used as voltage clamp at DC conditions. Operation in this mode may result in a drift of the zener voltage (increase of up to 1 V). RI OUT Power Inverse Diode Logic GND Inductive and overvoltage output clamp, OUT1...4 +Vbb VZ RGND Signal GND RL Power GND RGND = 150 , RI = 3.5 k typ, Temperature protection is not active during inverse current operation. V ON OUT Open-load detection, OUT1...4 OFF-state diagnostic condition: VOUT > 3 V typ.; IN low PROFET Power GND VON clamped to VON(CL) = 47 V typ. OFF I L(OL) V OUT Logic unit Open load detection Signal GND Semiconductor Group 8 BTS 712 N1 GND disconnect (channel 1/2 or 3/4) Ibb bb IN1 IN2 ST Vbb OUT1 PROFET OUT2 GND V GND Inductive load switch-off energy dissipation E bb E AS Vbb PROFET OUT L GND ZL ELoad V IN = ST V V V IN1 IN2 ST { R L EL ER Any kind of load. In case of IN = high is VOUT VIN - VIN(T+). Due to VGND > 0, no VST = low signal available. Energy stored in load inductance: GND disconnect with GND pull up (channel 1/2 or 3/4) EL = 1/2*L*I L While demagnetizing load inductance, the energy dissipated in PROFET is 2 EAS= Ebb + EL - ER= VON(CL)*iL(t) dt, IN1 V IN1 IN2 V IN2 ST GND PROFET OUT2 Vbb OUT1 with an approximate solution for RL > 0 : EAS= IL* L (V + |VOUT(CL)|) 2*RL bb ln (1+ |V IL*RL OUT(CL)| ) V V bb ST V GND Maximum allowable load inductance for a single switch off (one channel)5) L = f (IL ); Tj,start = 150C, Vbb = 12 V, RL = 0 L [mH] 1000 Any kind of load. If VGND > VIN - VIN(T+) device stays off Due to VGND > 0, no VST = low signal available. Vbb disconnect with energized inductive load 100 OUT1 IN2 ST PROFET OUT2 GND IN1 high Vbb 10 V bb For an inductive load current up to the limit defined by EAS (max. ratings see page 3 and diagram on page 9) each switch is protected against loss of Vbb. Consider at your PCB layout that in the case of Vbb disconnection with energized inductive load the whole load current flows through the GND connection. 1 1 1.5 2 2.5 3 IL [A] Semiconductor Group 9 BTS 712 N1 Typ. on-state resistance RON = f (Vbb,Tj ); IL = 1.8 A, IN = high RON [mOhm] 500 450 400 350 300 250 200 150 100 50 0 0 10 20 30 40 0 0 10 20 30 40 50 85C 25C -40C 0.25 0.75 Tj = -40C 25C 0.5 85C 150C Tj = 150C 1.25 Typ. ground pin operating current IGND = f (Vbb,Tj ); VIN = high (one channel on) IGND [mA] 1.5 1 Vbb [V] Vbb [V] Typ. standby current Ibb(off) = f (Tj ); Vbb = 9...34 V, IN1...4 = low Ibb(off) [A] 250 Typ. initial short circuit shutdown time toff(SC) = f (Tj,start ); Vbb =12 V toff(SC) [msec] 6 5 200 4 150 3 100 2 50 1 0 -50 0 50 100 150 200 0 -50 0 50 100 150 200 Tj [C] Ibb(off) includes four times the current I L(off) of the open load detection current sources. Tj,start [C] Semiconductor Group 10 BTS 712 N1 Timing diagrams Timing diagrams are shown for chip 1 (channel 1/2). For chip 2 (channel 3/4) the diagrams are valid too. The channels 1 and 2, respectively 3 and 4, are symmetric and consequently the diagrams are valid for each channel as well as for permuted channels Figure 1a: Vbb turn on: IN1 IN2 IN Figure 2b: Switching an inductive load, V bb ST V OUT1 V OUT V OUT2 I L ST open drain t t Figure 2a: Switching a lamp: IN Figure 3a: Turn on into short circuit: shut down by overtemperature, restart by cooling IN1 other channel: normal operation ST I L1 I V OUT L(SCp) I L(SCr) I L t ST t off(SC) t Heating up of the chip may require several milliseconds, depending on external conditions (toff(SC) vs. Tj,start see page 10) The initial peak current should be limited by the lamp and not by the initial short circuit current IL(SCp) = 7.5 A typ. of the device. Semiconductor Group 11 BTS 712 N1 Figure 3b: Turn on into short circuit: shut down by overtemperature, restart by cooling (two parallel switched channels 1 and 2) IN1/2 Figure 5a: Open load: detection in OFF-state, turn on/off to open load IN1 IN2 I L1 channel 2: normal operation +I L2 I L(SCp) VOUT1 I L(SCr) I L1 channel 1: open load t ST1/2 ST t td(ST,OL3) depends on external circuitry because of high impedance *) IL = 30 A typ off(SC) t d(ST OL3) t d(ST OL3) t Figure 4a: Overtemperature: Reset if Tj Figure 6a: Undervoltage: IN ST V bb V bb(under) V Vbb(u cp) Vbb(u rst) OUT V OUT T J t ST open drain t Semiconductor Group 12 BTS 712 N1 Figure 6b: Undervoltage restart of charge pump V on VON(CL) off-state on-state V bb(over) V V V bb(u rst) bb(o rst) bb(u cp) V bb(under) IN = high, normal load conditions. Charge pump starts at Vbb(ucp) = 5.6 V typ. Figure 7a: Overvoltage: IN Vbb V ON(CL) Vbb(over) V bb(o rst) V OUT ST off-state V bb t Semiconductor Group 13 BTS 712 N1 Package and Ordering Code Standard P-DSO-20-9 BTS712N1 Ordering Code Q67060-S7001-A2 All dimensions in millimetres 1) Does not include plastic or metal protrusions of 0.15 max per side 2) Does not include dambar protrusion of 0.05 max per side Definition of soldering point with temperature Ts: upper side of solder edge of device pin 15. Pin 15 Printed circuit board (FR4, 1.5mm thick, one layer 70m, 6cm2 active heatsink area) as a reference for max. power dissipation Ptot, nominal load current IL(NOM) and thermal resistance Rthja Semiconductor Group 14 |
Price & Availability of BTS712N1 |
|
|
All Rights Reserved © IC-ON-LINE 2003 - 2022 |
[Add Bookmark] [Contact Us] [Link exchange] [Privacy policy] |
Mirror Sites : [www.datasheet.hk]
[www.maxim4u.com] [www.ic-on-line.cn]
[www.ic-on-line.com] [www.ic-on-line.net]
[www.alldatasheet.com.cn]
[www.gdcy.com]
[www.gdcy.net] |