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HM530281R Series 331,776-word x 8-bit Frame Memory ADE-203-251B Rev. 1.0 June 6, 1997 Description The HM530281R series memory products provide completely asynchronous I/O and operate at the high speed of 50 MHz. The HM530281R series memory products provide reset, jump, and line increment/hold pointer control functions that can be used in synchronization with independent clocks on each of the I/O ports. Memory can be accessed immediately without any waiting period after the execution of these functions. In addition to the FIFO function, the 281R series products support an address structure that is compatible with HDTV, NTSC, and PAL standards, and can be used in a wide range of applications, such as noise reducers, TBC (time-based correction), inter-frame YC separation, and special function modes (e.g., multi-freeze, P-in-P) in the digital TV, VCR, and video camera application. They are also appropriate for use as inter-system speed conversion buffer memories in communications systems, as cache memories of HDD and MOD, and as frame buffer of VGA. Features * Organization: 331,776-word x 8-bit * Completely asynchronous operation of the serial read port and write port. Internal generation of read and write addresses Internal memory operation control provided on-chip * High speed read/write cycle time: 50 MHz * Reset, jump functions Independent execution for read and write ports Can be executed with arbitrary timing Allow immediate access after execution (read/write) (for the jump function, when the address setup is complete) Jump address specifiable in 32-word units * 2 dimensional address * Line increment/hold address pointer control function * Window scan function Datasheet Title * Can handle HDTV, NTSC, and PAL standards Line length: Up to 1152 bits (Arbitrary line lengths can also be handled by using the line reset function.) Line count: Up to 324 lines * Built-in self-refresh eliminates the need for external refresh control. * Power supply voltage: V CC = 5.0 V 10%. Ordering Information Type No. HM530281RTT-20 HM530281RTT-25 HM530281RTT-34 HM530281RTT-45 Cycle Time 20 ns 25 ns 34 ns 45 ns Memory Organization 331,776 words x 8 bits*2 1152 dots x 288 lines x 8 bits*3 1024 dots x 324 lines x 8 bits Package 44-pin TSOP (TTP-44DB) Notes: 1. Selectable following two kinds of addressing mode by mode pins 2. 1 dimensional addressing mode 3. 2 dimensional addressing mode Pin Arrangement Din0 Din1 Din2 Din3 Din4 Din5 Din6 Din7 VSS VCC WE CGW WCK WRS WLRS WCLR WWND WAS WAD MODE0 MODE1 TEST0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 (Top view) 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 24 23 Dout0 Dout1 Dout2 Dout3 Dout4 Dout5 Dout6 Dout7 VSS VCC OE CGR RCK RRS RLRS RCLR RWND RAS RAD TEST1 TEST2 TEST3 2 Datasheet Title Pin Description Functions Symbol Din0 to Din7 Dout0 to Dout7 WCK RCK WRS RRS WE OE CGW CGR WAS WAD RAS RAD WLRS RLRS WWND RWND WCLR RCLR MODE 0 to 1 VCC VSS TEST0 to TEST3 2 dimensional address Data input Data output Write clock Read clock Write reset Read reset Write enable Output enable Write clock gate Read clock gate Write address set Write address Read address set Read address Write line reset Read line reset Write window mode Read window mode Write clear Read clear Mode selection input Power supply Ground Connect to ground 1 dimensional address Data input Data output Write clock Read clock Write reset Read reset Write enable Output enable Write clock gate Read clock gate Write address set Write address Read address set Read address VCC or GND VCC or GND VCC or GND VCC or GND VCC or GND VCC or GND Mode selection input Power supply Ground Connect to ground 3 Datasheet Title Block Diagram 32-word x8 Write data register Write data buffer 32-word x8 Memory array 32-word x8 32-word x8 Read data register x8 Din WE Read data buffer x8 Dout OE 1152 dot x 288 line x 8*1 1024 dot x 324 line x 8*1 10368 dot x 32 word x 8*1 WCK CGW WRS WAS WAD WLRS WWND WCLR Write counter Memory controller Read counter RCK CGR Refresh counter RRS RAS RAD RLRS RWND RCLR Note : 1. Selected by the mode pin Absolute Maximum Ratings Parameter Pin voltage *1 Power dissipation Operating temperature Storage temperature Storage temperature (when biased) Note: Symbol VT PT Topr Tstg Tbias Value -1.0 to +7.0 1.0 0 to +70 -55 to +125 -10 to +85 Unit V W C C C 1. The permissible values with respect to VSS. 4 Datasheet Title Recommended DC Operating Conditions (Ta = 0 to +70C) Parameter Power supply voltage Symbol VCC VSS Input voltages VIH VIL Note: Min 4.5 0 2.7 -0.5 *1 Typ 5 0 -- -- Max 5.5 0 6.5 0.6 Unit V V V V 1. When the pulse width is under 10 ns, VIL min = -3.0 V. DC Characteristics (VCC = 5.0 V 10%, VSS = 0 V, Ta = 0 to +70C) HM530281-20 HM530281-25 HM530281-34 HM530281-45 Test Parameter Symbol Min Typ Max Min Typ Max Min Typ Max Min Typ Max Unit Conditions Operating power supply current Standby power supply current Input leakage current Output leakage current Output voltages I CCA -- 110 135 -- 90 120 -- 70 95 -- 55 75 mA Iout = 0, t WCC = tRCC = Min VCC = 5.5 V WCK, RCK = "L" fix VCC = 5.5 V, Vin = VSS to VCC OE = Vin Vout = VSS to VCC I OL = 2.1 mA I OH = -1.0 mA I CCS -- 15 25 -- 15 25 -- 15 25 -- 15 25 mA I LI -10 -- 10 -10 -- 10 -10 -- 10 -10 -- 10 mA I LO -10 -- 10 -10 -- 10 -10 -- 10 -10 -- 10 mA VOL VOH -- 2.4 -- -- 0.4 -- -- 2.4 -- -- 0.4 -- -- 2.4 -- -- 0.4 -- -- 2.4 -- -- 0.4 -- V V Capacitance*1 Parameter Input capacitance Output capacitance Note: Symbol Cin Cout Typ -- -- Max 5 7 Units pF pF Test Conditions Vin = 0 V Vout = 0 V 1. These parameters are sampled values, not values measured for all units. 5 Datasheet Title AC Characteristics Test Conditions * * * * Input pulse level: V SS to 3.0 V Input rise/fall time: 3 ns I/O timing reference level: 1.5 V Output load: 1 TTL + 50 pF (including jig and scope capacitances) HM530281R-20 HM530281R-25 HM530281R-34 HM530281R-45 Parameter Write clock cycle time Symbol Min t WCC 20 8 8 7 7 5 6 7 7 5 6 20 8 8 7 7 -- 6 0 -- 0 7 7 7 7 Max -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 18 -- -- 18 15 -- -- -- -- Min 25 10 10 8 8 5 6 8 8 5 6 25 10 10 8 8 -- 6 0 -- 0 8 8 8 8 Max -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 23 -- -- 20 18 -- -- -- -- Min 34 12 12 10 10 5 6 10 10 5 6 34 12 12 10 10 -- 6 0 -- 0 10 10 10 10 Max -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 25 -- -- 25 20 -- -- -- -- Min 45 15 15 10 10 5 6 10 10 5 6 45 15 15 10 10 -- 6 0 -- 0 10 10 10 10 Max -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 30 -- -- 25 20 -- -- -- -- Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns Write clock pulse width (high) t WC Write clock pulse width (low) WRS setup time WRS hold time Data input setup time Data input hold time CGW setup time CGW hold time WE setup time WE hold time Read clock cycle time t WCP t WRS t WRH t DS t DH t WGS t WGH t WES t WEH t RCC Read clock pulse width (high) t RC Read clock pulse width (low) RRS setup time RRS hold time Access time from RCK Output hold time Output enable time Output enable access time Output disable time CGR setup time CGR hold time WAS setup time WAS hold time t RCP t RRS t RRH t RAC t OH t OLZ t OAC t OHZ t RGS t RGH t WSS t WSH 6 Datasheet Title AC Characteristics (cont) HM530281R-20 HM530281R-25 HM530281R-34 HM530281R-45 Parameter RAS setup time RAS hold time Write address input setup time Symbol Min t RSS t RSH t WAS 7 7 5 6 5 6 7 7 7 7 7 7 7 7 7 7 7 7 Max -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Min 8 8 5 6 5 6 8 8 8 8 8 8 8 8 8 8 8 8 Max -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Min 10 10 5 6 5 6 10 10 10 10 10 10 10 10 10 10 10 10 Max -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Min 10 10 5 6 5 6 10 10 10 10 10 10 10 10 10 10 10 10 Max -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns Write address input hold time t WAH Read addres s input set up time t RAS Read address input hold time t RAH WLRS setup time WLRS hold time RLRS setup time RLRS hold time WCLR setup time WCLR hold time RCLR setup time RCLR hold time WWND setup time WWND hold time RWND setup time RWND hold time t WLS t WLH t RLS t RLH t WCLS t WCLH t RCLS t RCLH t WWDS t WWDH t RWDS t RWDH 7 Datasheet Title Input and Output Pin Functions DIN0 to D IN 7 (data input) Input: The DIN pins input 8 bits of data. Data is input on the rising edge of the cycle of WCK that follows a low level on both CGW and WE. DOUT0 to D OUT7 (data output) Output: The DOUT pins output 8 bits of data. Data output is synchronized with the RCK clock, and the access time is specified from the rising edge of the RCK cycle. WCK (write clock) Input: WCK is the write clock input pin. The input of write data is synchronized with this clock. Write data is input on the rising edge of the cycle of WCK that follows a low level on both CGW and WE, and when CGW is low, the internal write address pointer is incremented at the same time. Input of the write jump address is also synchronized with this clock. The 14 bits or 15 bits of the write jump address are read in sequentially from the WCK cycle that set WAS low, irrespective of write data acquisition. RCK (read clock) Input: RCK is the read clock input pin. Read data is output in synchronization with this clock when both CGR and OE are low, and when CGR is low, the internal read address pointer is incremented at the same time. Input of the read jump address is also synchronized with this clock. The read jump address is read in sequentially starting at the RCK cycle in which R A S was set low, independently of read data output. WRS (write address pointer reset) Input: WRS is a reset signal input that resets the write address pointer to 0 when WAS and WLRS are high, resets to the head of the line currently being written when WAS is high and WLRS is low, and jumps to the preset write jump address when WAS is low. *1 Only the falling edge of this reset input is detected, and, on the first WCK cycle following that falling edge, a write cycle to the set address is started immediately. RRS (read address pointer reset) Input: RRS is a reset signal input that resets the read address pointer to 0 when RAS and RLRS are high, resets to the start of the line currently being read when RAS is high and RLRS is low, and jumps to the read jump address when RAS is low. *1 Only the falling edge of this reset input is detected, and, on the first RCK cycle following that falling edge, a read cycle at the set address is started immediately. WE (write enable) Input: WE is an input signal that controls the enabling/disabling of the data input pins. When WE is low, input data is acquired on the WCK cycle, and when WE is high, data input is disabled and the previous memory data is maintained. Note that the write address pointer is incremented by the WCK write clock without regard for the level of WE. OE (output enable) Input: OE is an input signal that enables/disables the data output pins. When OE is low, data output is enabled, and when high, data output is disabled and the output pins go to the high impedance state. Note that the read address pointer is incremented by the RCK read clock without regard for the level of OE. Therefore, data can be jumped over during read simply by disabling output with OE. CGW (clock gate for write) Input: CGW is an input signal that enables/disables incrementing of the internal write address pointer. When C G W is low, the write address pointer is incremented in synchronization with the WCK write clock, and when high, incrementing is stopped. Therefore time axis compression can be easily implemented without stopping the write clock by using CGW. 8 Datasheet Title CGR (clock gate for read) Input: C GR is an input signal that enables/disables incrementing of the internal read address pointer. When CGR is low, the read address pointer is incremented in synchronization with the RCK read clock, and when high, incrementing is stopped. Therefore time axis expansion can be easily implemented without stopping the read clock by using CGR. WAS (write address set and jump) Input: WAS is an input signal that initiates write jump address input when WRS is high and jumps to the previously input write jump address when WRS is low. The falling edge of this input signal is detected, and either a write jump address input is initiated or a jump to the previously input write jump address is executed on the first WCK cycle following the fall of WAS. WAD (write jump address) Input: WAD is the input pin for the write jump address. The 14/15 bits of the write jump address are read in sequentially from the high order bit, starting at the WCK cycle (when WRS was high) in which WAS was set low.*2 RAS (read address set and jump) Input: RAS is an input signal that initiates read jump address input when RRS is high and jumps to the previously input read jump address when RRS is low. The falling edge of this input signal is detected, and either the read jump address input is initiated or the jump to the previously input read jump address is executed on the first WCK cycle following the fall on RAS. RAD (read jump address) Input: RAD is the input pin for the read jump address. The 14/15 bits of the write jump address are read in sequentially from the high order bit, starting at the RCK cycle (when R R S was high) in which R AS was set low. *2 9 Datasheet Title WLRS (write line reset) Input (in 2 dimensional addressing mode): WLR S is an input pin for resetting the write address pointer to the start of the line from an arbitrary dot for each line.*3 Only the falling edge of this signal is detected, and, on the first WCK cycle following that falling edge, the write address pointer is set to the head of the next line when WRS is high, and to head of the current line when WRS is low.*3 RLRS (read line reset) Input (in 2 dimensional addressing mode): R LR S is an input pin for resetting the read address pointer to the start of the line from an arbitrary dot for each line.*3 Only the falling edge of this signal is detected, and, on the first RC K cycle following that falling edge, the write address pointer is set to the head of the next line when RRS is high, and to head of the current line when RRS is low.*3 WWND (write window scan) Input (in 2 dimensional addressing mode): WWND is an input signal that specifies the use of the window scan function. When executing a write jump with WRS and WAS low, if WWND is set low at the same time, a scan of the window region that takes that write jump address as its starting point will begin (see note below). RWND (read window scan) Input (in 2 dimensional addressing mode): RWND is an input signal that specifies the use of the window scan function. when executing a read jump with RRS and RAS low, if RWND is set low at the same time, a scan of the window region that takes that read jump address as its starting point will begin.*4 WCLR (write clear) Input: WCLR is an input signal that, independently of the levels on WRS, WAS, WLRS and WWND resets the write address pointer to 0 and clears the window scan function. This function is executed immediately in the WCK cycle in which WCLR was set low. This clear operation should also be performed after applying power to the HM530281R. RCLR (read clear) Input: RCLR is an input signal that, independently of the levels on RRS, RAS, RLRS and RWND resets the read address pointer to 0 and clears the window scan function. This function is executed immediately in the RCK cycle in which RCLR was set low. This clear operation should also be performed after applying power to the HM530281R. Notes: 1. The reset destination in window scan mode changes as follows. Reset to 0: Reset to the window start. Reset to line start: Reset to the point at the left edge of the window for the line 2. Addressing Mode 1 dim. add. (FIFO) 2 dim. add. (1) 2 dim. add. (2) Address Structure 0 to 10,367 blocks Input Address Address bits A13 to A0 32 horizontal blocks by 324 vertical lines Line address bits V 8 to V0, horizontal address bits H4 to H0 36 horizontal blocks by 288 vertical lines. Line address bits V 8 to V0, horizontal address bits H5 to H0 3. When window scan mode is set, the reset is to the point at the left edge of the window for the line. 4. When window scan is set, the horizontal address of the pointer reset destination when increment/hold is executed will be the left edge of the window. Also, when a reset is executed, the pointer will be reset to the starting point of the window. Thus it is possible to scan arbitrary window regions within the screen independently for read and write by using these line reset and reset functions. 10 Datasheet Title Memory Structure The memory is organized as 331,776-word of 8-bit each, and these words can be accessed sequentially, since the address pointer can be incremented by inputting a clock signal. Addresses are allocated corresponding to 32 word blocks. The mode pins switch between the three addressing modes shown below. Mode 0 0 1 0 Mode 1 0 0 1 Addressing Mode 1 dim. add. (FIFO) 2 dim. add. (1) 2 dim. add. (2) Address Structure 0 to 10,367 blocks 32 horizontal blocks by 324 vertical lines 36 horizontal blocks by 288 vertical lines Capacity 331,776 words 1024 dots by 324 lines 1152 dots by 288 lines Notes: 1. In 1 dimensional addressing mode, blocks 0 to 10367 are accessed cyclically. 2. In the 2 dimensional addressing modes, the line head can be reset at an arbitrary dot on each line. Operations Write Write operation: When the WE and CGW inputs are low, 8 bits of write data are input in synchronization with the WCK clock. The input data is read in to the word indicated by the address pointer on the next rising edge of the WCK cycle. This allows read data and write data to be handled with the same clock, and cascade connections to be easily implemented. Write reset operations: When CGW is low, by setting WRS low, the write address pointer can be set immediately on that WCK cycle to the address 0 block head. This operation can be executed independently of the input level of WE. (See `Notes on usage' 15 on the operation when CGW is high.) Write address pointer increment operations: The write address pointer is incremented in synchronization with WCK when CGW is low. It is possible to apply a write mask in WCK clock units by setting the WE input high. In this case, the previous memory data will be retained. The write address pointer increment function can be stopped by setting the CGW input high. This allows time axis compression to be implemented easily. (See `Notes on usage' 7, 9 and 10 for interval specifications of write system reset operations.*1) Note: 1. The write system reset operation stands for write reset, write jump, write window reset, write line reset and write clear. 11 Datasheet Title WE and CGW Input Level, Write Address Pointer, and Data Input State Relationship WCK Rising Edge CGW L L H WE L H -- Stopped Internal Write Address Pointer Incremented Data Input enable disable (memory data is retained) Note: Data is input when the WE input is low. Read Read operation: 8 bits of read data are output in synchronization with the RCK clock when the OE and CGR inputs are low. The access time is stipulated from the rising edge of the RCK clock. Read reset operations: When CGR is low, by setting RRS low, the read address pointer can be set immediately on that RCK cycle to address 0 and the data will then be output. This operation can be performed independently of the input level of OE. (See `Notes on usage' 14 on the operation when CGR is high.) Read address pointer increment operations: The read address pointer is incremented in synchronization with RCK when CGR is low. Data outputs go to the high impedance state when the OE input is set high. The reset address pointer increment function can be stopped by setting the CGR input high. This allows time axis expansion to be implemented easily. (See `Notes on usage' 7, 8 and 10 for interval specifications of read system reset operations.*2) Note: 2. The read system reset operations stands for read reset, read jump, read window reset, read line reset and read clear. Relation Between the OE and CGR Input Levels and the Read Address Pointer and Data Output States RCK Rising Edge CGR L L H H OE L H L H Stopped Internal Read Address Pointer Incremented Data Output Output High impedance Output data held High impedance Note: Data is input when the OE input is low. Line Reset (write line reset and read line reset, in 2 dimensional addressing modes) When the 281R series products are used in 2 dimensional addressing modes, the line length can be set to be either 1024 dots (2 dimensional (1)) or 1152 dots (2 dimensional (2)). In these modes, after accessing the 12 Datasheet Title data at the last dot (address) on each line, address pointer incrementing is stopped. Access is restarted at either the first dot at the head of the next line or at the first dot at the head of the current line by executing either a line increment or a line hold, respectively. Also, since these line reset operations can be executed at any arbitrary point in the middle of a line, an arbitrary line length (of between 64 dots and the actual line length) can be realized. Line increment operation: In case clock gate signal (CGW, CGR) is low, the read and write line increment operations are executed by setting RLRS low and RRS high, and setting WLRS low and WRS high respectively. When these operations are executed, the next access goes immediately to the starting dot of the next line. Line hold operation: In case clock gate signal (CGW, CGR) is low, the read and write line hold operations are executed by setting RLRS and RRS low, and setting WLRS and WRS low respectively. When these operations are executed, the next access goes immediately to the starting dot of the current line. Note that the read line hold operation is invalid on the first line following a 0 reset or jump. In this case, the same effect can be achieved by re-executing the reset or jump operation (resetting only the H address to 0). If the reset interval specifications are met (see Notes on Usage 1 to 3), the line reset operation can be performed on an arbitrary RCK/WCK clock cycle without regard for the levels of the OE and WE inputs. (See `Notes on usage' 15 and 16 on the operation when clock gate signal (CGW, CGR) is high.) Jump (independent functions for read and write) It is possible to set the address pointer to the start address of an arbitrary block in 32 word units. After initializing a jump address setup for read and/or write, after 64 WCK or 64 RCK cycles, it is possible to execute a jump to that address (random access in 32 word by 8 bit units) independently for read and write. (See `Notes on usage' 12 on the jump operation to `0' address and line end address.) Jump address setup: The read and write jump addresses are serially input independently from the RAD and WAD pins in synchronization with the RCK and WCK clock inputs respectively. Address input start is enabled by setting the RAS and/or WAS inputs low for read and write respectively, and 14/15 bits of jump address are input sequentially starting with that cycle.*10 Note that the read and write operations can continue independently of this address input operation. Jump address setup is executed regardless of WE, CGW and OE, CGR. Following the start of address input, it is possible to mask the input of address bits below an arbitrary bit position by returning RAS or WAS to the high level at the desired bit position. This can be convenient in applications that need to jump a fixed interval, since the low order bits of the address will be fixed. When all 14 bits of an address are to be input, be sure to hold RAS and WAS low for the full 14-clock period. Jump operation: In case clock gate signal (CGW, CGR) is `L', the jump operation is executed by setting RRS and RAS low for read, and by setting WRS and WAS low for write, and the address set is accessed immediately from that RCK or WCK cycle. Note that as long as the interval specifications listed in Notes 7 to 9 are met, the jump operation can be executed on any RCK or WCK cycle without regard for the values of OE and WE. (See `Notes on usage' 14 and 15 on the operation, when clock gate signal (CGW, CGR) is high.) 13 Datasheet Title Window Scan (independent functions for read and write) The window scan function can be used with either the 2 dimensional (1) or (2) addressing modes, and is a function which scans a rectangular region with an arbitrary starting point. The jump address setup function (see Jump address setup above) is used to specify the starting point Initiating window scan: The window scan function is started by setting WWND to low for read or RWND low for write, and executing a read or write jump operation (see Jump operation above). Window scan will start immediately from that cycle. Window scan operation: When the window scan function is started, one of the functions described below will be executed independently for read and write. *11 Also note that as long as the interval conditions listed in Notes 7 to 9 are met, these operations can be executed at arbitrary dots without regard for the address block organization. Clearing window scan: The window scan function is turned off either by executing a reset or jump with R WND (for read) or WWND (for write) set high, or by executing the clear operation described in section Clear below. Note that both setting and clearing window scan mode are executed independently of OE and WE. (See `Notes on usage' 14 and 15 on the operation when clock gate signal (CGW, CGR) is high.) Operation Reset Line increment Line hold Address Pointer Control Reset to the first dot at the start of the window. Reset to the first dot at the left edge of the window on the next line. Reset to the first dot at the left edge of the window on the current line. 14 Datasheet Title Overview of the window scan operation: 0 0 0 31 1 63 2 Horizontal (dot) Horizontal address (H) 1023(1151) 31(35) First point of the screen First point of the window (M, N) Window area Vertical (line) (V, N) (V + 1, N) Re Line hold set (V, N + n) ent Line increm (M + m, N + n) 323 (287) Note: 1. M and N are addresses, M is in line units, N is units of 32 dots, and m and n are in line and dot units respectively. Clear (independent functions for read and write) The clear function both resets the address pointer to 0 without regard for the value on WRS, WAS, WLRS, WWND, RRS, RAS, RLRS and RWND, and if window mode is set, clears window mode. Clear Operation: When clock gate signal (CGW, CGR) is low, the clear operation can be executed on any cycle by setting the RCLR pin low for read and the WCLR pin low for write. When the interval conditions listed in Notes on usage 7 to 10 are met, clear operation is executed at any time without regard of the level on WE and OE. (See `Notes on usage' 14 and 15 on the operation when clock gate signal (CGW, CGR) is high) Access of New and Previous Data New data access (follow-up read out of data currently being written): Written data can be read out 160 WCK cycles after it is written. However, it is necessary to execute the read jump address setup operation outside the time period between 32 WCK cycles before write to that address is started and 32 WCK cycles after write to that address is completed. 15 Datasheet Title * It is possible to read out the new data of 32 word block when jumping to an address at least 128 WCK clock cycles after write to that address was started. Note that in this case, there is more than enough time for the read jump address setup operation even if it is begun 32 or more clock cycles after the completion of the write operation. * It is possible to read out the new data of less than 32 word block when 128 WCK clock after write system reset was input. Starting and clearing window scan: Window off Start (Window jump) (Reset) (Line increment) (Line hold) (Jump) Clear (Reset) (Jump) (Clear) Window on New setup (Window jump) (Address setup) (Reset to the window origin point) (Line increment) (Line hold) At least 96 WCK clock are necessary between completion 32 word block data input and starting previous address of 32 word block data output. Generally this mean, 160 WCK clock separation between write and read address pointer. Previous data access (reading out data prior to that of the current write operation): The previous data can be read out up to 32 WCK clock cycles after the write operation. Therefore, these memories can be used to provide delay times of between 160 and 331,808 (331,776 + 32) clock cycles. 16 Datasheet Title Power On Wait at least 100 s after power-on to begin operation. At this time the write and read address pointers are undefined. The following operation should be executed. * * * * CGW and CGR should be hold low. Reset cycle when 1 dimensional addressing mode. Clear cycle when 2 dimensional addressing mode. Dummy cycle of over 64 WCK and 64 RCK clock cycle. Then, initiate the desired operating mode by providing the signal input combination given by the truth tables below. Function Table Note: Description of operations of function table is based on the operation on condition CGW, WE and CGR, OE is low. 1 Dimensional Addressing Modes Write WCK Rising Edge WRS H L L H WAS H H L L Operation Normal state Reset Jump Address setup In the normal state, the write address pointer is incremented in synchronization with WCK. The write address pointer is reset to 0. Jump to the address A to which the write address pointer is set. The write jump address is input. Read RCK Rising Edge RRS H L L H RAS H H L L Operation Normal state Reset Jump Address setup In the normal state, the read address pointer is incremented in synchronization with RCK. The read address pointer is reset to 0. Jump to the address A to which the read address pointer is set. The read jump address is input. 17 Datasheet Title 2 Dimensional Addressing Modes (when window scan is not used) Write *1 Operation Levels At The Rise Of WCK WRS H WAS H WLRS H WWND WCLR H H Normal state Write Address Pointer Control Incremented in synchronization with WCK Reset to (0, 0) Jump to the set address A -- Write Jump Address -- Notes 2 L L H H L H L L H H H H H L L H H H H H H H H H H L Reset Jump Address set Line increment Line hold Clear -- -- Set 2 2 Reset to the first bit of the -- next line Reset to the first bit of the -- current line Reset to (0, 0) Note: (--: VIH or VIL) Read*1 Operation Levels At The Rise Of WCK RRS H L L H H L RAS H H L L H H RLRS H H H H L L RWND H H H H H H RCLR H H H H H H L Normal state Reset Jump Address set Line increment Line hold Clear Read Address Pointer Control Read Jump Address Notes 3 Incremented in -- synchronization with RCK Reset to (0, 0) Jump to the set address A -- -- Set Reset to the first bit of the -- next line Reset to the first bit of the -- current line Reset to (0, 0) -- 3 3 Note: (--: VIH or VIL) 18 Datasheet Title 2 Dimensional Address Modes (when window scan is not used) Write Operation Levels At The Rise Of WCK WRS L H WAS H H WLRS H H WWND WCLR H -- H H Reset Write Address Pointer Control Write Jump Window Mode After Window Window Address Execution Mode Off Mode On Notes Reset to (0, 0) -- -- Off -- 4 Normal state Incremented in synchronization with WCK Line increment To the first bit of the next line H H L -- H To the left -- edge of the window on the next line To the left -- edge of the window on the current line Set -- -- -- -- -- L H L -- H Line hold To the first bit of the current line -- H L L L -- L L L H -- H H H H -- -- H L L -- H H H H L Address set Jump Window jump Reset Clear -- Jump to the set address A Jump to the set address A Reset to the window origin point A Reset to (0, 0) -- Off On -- Off 6 Note: (--: VIH or VIL) 19 Datasheet Title Read Operation Levels At The Rise Of WCK Read Address Pointer Control Read Window Window Window Jump Mode After Mode Off Mode On Address Execution Notes Reset Reset to (0, 0) -- -- Off -- 5 RRS L H RAS H H RLRS H H RWND H -- RCLR H H Normal state Incremented in synchronization with RCK Line increment To the first bit of the next line H H L -- H To the left -- edge of the window on the next line To the left -- edge of the window on the current line Set -- -- -- -- -- L H L -- H Line hold To the first bit of the current line -- H L L L -- L L L H -- H H H H -- -- H L L -- H H H H L Address set Jump Window jump Reset Clear -- Jump to the set address A Jump to the set address A Reset to the window origin point A Reset to (0, 0) -- Off On -- Off 6 (--: VIH or VIL) * Notes on usage. 1. Hold the WWND and RWND pin high when window mode is not used. 2. The write address pointer is incremented up to the last dot on the current line, and then stopped. Writing is started immediately from the first dot on the next line by execution of the line increment operation. Also, writing is started immediately from the first dot on the current line by execution of the line hold operation. 3. The read address pointer is incremented up to the last dot on the current line, and then stopped. Reading is started immediately from the first dot on the next line by execution of the line increment operation. Also, reading is started immediately from the first dot on the current line by execution of the line hold operation. 4. The write address pointer is incremented up to the last address on the line, and then stopped. Writing is started immediately from the first dot on the next line or the left edge of the window by execution of the line increment operation. 20 Datasheet Title 5. The read address pointer is incremented up to the last address on the line, and then stopped. Reading is started immediately from the first dot on the next line or the left edge of the window by execution of the line increment operation. 6. It is possible to move directly from an old window to a new window in window mode by setting up a new jump address and executing a window setup jump operation. However, the new jump address should be input after access to the last line of the old window. 7. Read system reset operations (read reset, read jump, read window reset, read line reset and read clear) and the read address set up operation cannot be executed for consecutive RCK clock cycles. Similarly write system reset operations (write reset, write jump, write window reset, write line reset and write clear) and the write jump address setup operation cannot be executed for consecutive WCK clock cycles. 8. Read system reset (read reset, read jump, read window reset, read line reset and read clear) operations and read jump address set operations must be performed at times separated by at least 64 RCK clock cycles. (There is no need to use only 32 word addressing units, and these operations can be performed on any clock cycle). 9. Write system reset operations (write reset, write jump, write window reset, write line reset and write clear) must be performed at times separated by at least 64 WCK clock cycles. When address is input, write/read system reset can not be executed. 10. It is possible to input the write system reset in the middle of 32 word unit addressing. In this case, not only must the condition of note 8 be met, but furthermore, pairs of write system resets for units of less than 32 words must be separated by at least 160 WCK clock cycles. When the write system reset is executed at less than 32 words, the data up to the point to which the address pointer has advanced will be written, and the remaining data will retain the old values. (Note that after the completion of a write of less than 32 words, a write reset is required to write the data for the last address into the memory array.) 11. Addressing Mode 1 dim. add. (FIFO) 2 dim. add. (1) 2 dim. add. (2) Address Structure 0 to 10,367 blocks 32 horizontal blocks by 324 vertical lines 36 horizontal blocks by 288 vertical lines Input Address Address bit A13 to A0 Line address bits V8 to V0, horizontal address bits H4 to H0 Line address bits V8 to V0, horizontal address bits H5 to H0 12. Specifiable window sizes Horizontal: Between 64 dots and the length of the line. Vertical: Between 1 line and the maximum number of lines. 13. Location 0 and line end cannot be specified as a jump address. Use a reset to access location 0. 14. Any number of read system reset operations can be input when CGR is high but in this case the only first reset is effective. This read system reset operation (read reset, read jump, read window reset, read line reset and read clear) is executed at the rising edge of the RCK just after CGR is set low. 15. Any number of write system resets can be input when CGW is high, but the only first reset is effective. This write system reset operation is executed at the rising edge of the WCK just after CGW is set to low. 16. When window scan mode is used any case after power on, WWND and WRS or RWND and RRS pins are should be input same signal. 21 Datasheet Title Supplement If the read system reset interval (at least 64 RCK clock cycles) of note 7, or the write system reset interval for less than 32 word units (and at least 160 WCK clock cycles) are not provided (see note 9), it is possible for the 32 words of data of the first address after the reset to be invalid, or for the first write of less than 32 words following the write reset to fail to occur. However, even in this case, address pointer control will function correctly, and valid data will be output for the second and following addresses. (However, in this case the condition of note 8 and the 32 clock or longer read system reset/read jump address interval must be provided.) Timing Waveforms Write Cycle Write address reset Cycle N - 1 WCK WRS WAS Din D(N - 2) D(N - 1) Add 'X' D(N) t WRS t WRS Cycle N Cycle 0 t WCC t WC t WRT Cycle 1 t WCP t DS t DH D(0) Add '0' D(1) D(2) High Cycle 2 Note: The write address pointer is reset to 0 starting with the WRS low cycle. Only the falling edge of the WRS signal is detected. Adequate margin is provided if the rise occurs at least one clock cycle before the next fall. 22 Datasheet Title Write clock gate Clock gate cycle t WCC Cycle N - 1 WCK WRS WAS Din CGW WE D(N - 2) D(N - 1) Cycle N Cycle N + 1 Cycle N + 2 High High D(N) t WGS t WGH D(N + 1) D(N + 2) Low Note: During cycles where CGW is high, the write address pointer is not incremented, and the DIN data is not written. Write enable Cycle N - 1 WCK WRS WAS Din CGW WE Note: D(N - 2) D(N - 1) t WEH t WES t WEH Although the write address pointer is incremented on a cycle where WE is high, the DIN data is not written, and the previous memory data is retained. D(N) t WES D(N + 2) High High D(N + 3) Low Cycle N t WCC Cycle N + 2 Cycle N + 3 23 Datasheet Title Read Cycle Read address reset Cycle N - 1 RCK RRS RAS Dout D(N - 2) D(N - 1) Add'X' Note: D(N) t RRS t RRS Cycle N Cycle 0 t RCC Cycle 1 t RCP t OH D(0) D(1) Add'0' D(2) Cycle 2 t RC t RRH t RAC High The read address pointer is reset to 0 from the cycle where RRS was low. Only the falling edge of the RRS signal is detected. Adequate margin is provided if the rise occurs at least one clock cycle before the next fall. Read clock gate Clock gate cycle t RCC High t RAC D(N - 2) D(N - 1) t RGS D(N) t RGH t OH D(N + 1) D(N + 2) High Cycle N - 1 RCK RRS RAS Dout CGR OE Note: Cycle N Cycle N + 1 Cycle N + 2 Low During cycles where CGR is high, the read address pointer is not incremented, and the output data is retained. 24 Datasheet Title Output enable Disable cycle (N + 1) t RCC High t RAC D(N - 2) D(N - 1) D(N) t OHZ High-Z t OLZ t OAC During cycles where OE is high, the output goes to the high impedance state, and the read address pointer is incremented. D(N + 2) D(N + 3) Low High Cycle N - 1 RCK RRS RAS Dout CGR OE Note: Cycle N Cycle N + 2 Cycle N + 3 Line Reset Write line increment t WCC N-1 WCK WLRS WRS Din WWND WCLR Note: The line address V is incremented, and the horizontal address H is reset to 0. t WLS t WLS t DS D(N - 1) Add(V, H) D(N) N 0 t WLH t DH D(0) D(1) Add(V + 1.0) High High D(2) High 1 2 25 Datasheet Title Read line increment t RCC N-1 RCK RLRS RRS Dout RWND RCLR Note: The line address V is incremented, and the horizontal address H is reset to 0. t RLS t RLS D(N - 1) Add (V, H) D(N) N 0 t RLH t RAC D(0) t OH D(1) Add (V + 1,0) High High D(2) High 1 2 Write line hold t WCC N-1 WCK WLRS WRS Din t WLS t WLS t WRS t WRS t DS D(N - 1) Add(V, H) D(N) t WLH t WRH t DH D(0) D(1) Add(V, 0) High High D(2) High N 0 1 2 WWND WCLR Note: The line address V is held as it is, and the horizontal address H is reset to 0. 26 Datasheet Title Read line hold t RCC N-1 RCK RLRS RRS Dout D(N - 1) Add(V, H) RWND RCLR Note: The line address V is held as it is, and the horizontal address H is reset to 0. t RLS t RLS t RRS t RRS N 0 t RLH t RRH D(N) t RAC D(0) 1 2 t RDH D(1) Add(V, 0) D(2) High High High Jump Address Setup (1 Dimensional Addressing Mode) Write address setup Write address setup 0 WCK t WSS WAS WAD WRS Din Valid Valid Valid Valid Valid Valid D(N) D(0) D(1) Add 'WA' t WAS t WAH A12 A11 A1 A0 t WSH 1 2 Write jump 13 63 0 1 At least 64 CLK cycles 12 A13 The write jump address WA is (A13 , A 12 , ... A 0 ) Note: After 64 cycles have passed following the start of write address setup, a jump to the set address can be performed at any time. 27 Datasheet Title Read address setup Read address setup 0 1 RCK RAS t RAS RAD RRS Dout Valid Valid Valid Valid Valid D(N) D(0) D(1) Add 'RA' t RSS t RAH A12 A11 A1 A0 Read jump 63 0 2 At least 64 CLK cycles 12 13 t RSH 1 A13 The read jump address RA is (A13 , A 12 , ... A0 ) Note: After 64 cycles have passed following the start of read address setup, a jump to the set address can be performed at any time. Read and write address setup can be performed asynchronously. Jump Address Setup (2 Dimensional Addressing Mode 1) Write address setup (2 dimensional addressing: 324 line x 1024 dot mode) Write address setup 0 WCK WAS t WAS WAD WRS Din Valid Valid Valid Valid Valid Valid Valid Valid D(N) D(0) D(1) V8 t WSS Line address V t WAH V7 V0 H4 H3 H0 t WSH Horizontal address H 1 8 Write jump 0 63 At least 64 CLK cycles 9 10 13 1 The write jump address W (V, H) is (V8 , ... , V0 , H 4 , ... , H0 ) Note: Add'W(V, H)' The jump to the set address can be performed at any time once the required 64 cycles have passed following the start of write address setup. 28 Datasheet Title Read address setup (2 dimensional addressing: 324 line x 1024 dot mode) Read address setup At least 64 CLK cycles 0 1 8 9 10 13 RCK t RSH t RSS Line address V Horizontal address H RAS t RAH t RAS V8 V7 V0 H4 H3 H0 RAD RRS Dout Valid Valid Valid Valid Valid Valid Valid D(N) D(0) D(1) Add 'R(V, H)' Read jump 0 63 1 The read jump address R (V, H) is (V8 , ... , V0 , H4 , ... , H 0 ) Note: The jump to the set address can be performed at any time once the required 64 cycles have passed following the start of read address setup. Read and write address setup can be performed asynchronously. Jump Address Setup (2 Dimensional Addressing Mode 2) Write address setup (2 dimensional addressing: 288 line x 1152 dot mode) Write address setup At least 64 CLK cycles 0 1 8 9 10 14 WCK t WSH t WSS Line address V Horizontal address H WAS t WAH t WAS WAD WRS Din Valid Valid Valid Valid Valid Valid Valid Valid D(N) D(0) D(1) V8 V7 V0 H5 H4 H0 Write jump 0 63 1 The write jump address W (V, H) is (V8 , ... , V0 , H5 , ... , H0 ) Note: Add 'W(V, H)' The jump to the set address can be performed at any time once the required 64 cycles have passed following the start of write address setup. 29 Datasheet Title Read address setup (2 dimensional addressing: 288 line x 1152 dot mode) Read address setup At least 64 CLK cycles 0 1 8 9 10 14 RCK t RSH t RSS Line address V Horizontal address H RAS t RAH t RAS V8 V7 V0 H5 H4 H0 RAD RRS Dont Valid Valid Valid Valid Valid Valid Valid D(N) D(0) D(1) Add'R(V, H)' Read jump 0 63 1 The read jump address R (V, H) is (V8 , ... , V0 , H 5 , ... , H0 ) Note: The jump to the set address can be performed at any time once the required 64 cycles have passed following the start of read address setup. Read and write address setup can be performed asynchronously. Address input mask Address setup 0 1 WCK (RCK) t WSS (t RSS) WAS (RAS) t WAS (t RAS) WAD (RAD) WRS (RRS) In this example, only the line address is re-input, and the horizontal address retains its previously set value. Note: After the start of read or write jump address setup, if RAS or WAS respectively is returned to the high level at an arbitrary bit position, the address bits input thereafter are masked, and the corresponding bits retain their previous values. t WAH (t RAH) V8 V7 V6 V0 Jump 63 0 2 At least 64 CLK cycles 8 9 t WSH (t RSH) 10 30 Datasheet Title Jump Write jump N-1 WCK t WRS WRS WAS t WRS t WSS t WSS t DS t DH Din D(N - 2) Add 'X' Note: D(N - 1) D(N) t DS t DH D(0) Add 'WA' D(1) D(2) t WSH t WRH N 0 t WCC 1 2 WA is the address input in the previous write address setup cycle. Read jump N-1 RCK t RRS RRS RAS Dout t RRS t RSS t RSS D(N - 1) Add 'X' Note: D(N) t RSH t RAC D0 t OH D1 Add 'RA' D2 t RRH N 0 t RCC 1 2 RA is the address input in the previous read address setup cycle. 31 Datasheet Title New/Previous Data Access New data access (address reset) 0 WCK WE CGW WRS WAS Din New 0 New 1 New 2 Add '0' RCK CGR RRS RAS OE Dout New 0 New 1 New 2 Add '0' Note: Written data can be read out 160 WCK clock cycles after it was written. High Add '4' 0 1 Add '5' 2 High New 160 New 161 New 162 1 2 3 160 161 162 32 Datasheet Title Previous data access (address reset) 0 WCK WE CGW WRS WAS Din New 0 New 1 New 2 Add '0' 0 RCK CGR RRS RAS OE Dout Note: Previous 0 Previous 1 Previous 2 1 2 3 32 33 34 High New 32 New 33 New 34 1 Add '1' 2 High Add '0' Previous data can be read out up to 32 WCK clock cycles after the write operation. 33 Datasheet Title New data access (address jump) (example where the read and write jump addresses are to the same location) 0 WCK WE CGW WRS WAS Din New 0 New 1 Add 'A' RCK CGR RRS RAS OE Dout New 0 New 1 New 2 Add 'A' Note: Written data can be read out 160 WCK clock cycles after it was written. However, it is necessary to execute the read jump address setup operation outside the time period between 32 WCK cycles before the start of write to that address and 32 WCK cycles after the completion of write to that address. Add 'A + 4' 0 New 160 New 161 New 162 1 2 13 160 161 162 Add 'A + 5' 1 2 34 Datasheet Title Previous data access (address jump) (example when the read and write jump addresses are to the same location) 0 WCK WE CGW WRS WAS Din New 0 New 1 Add 'A' 0 RCK CGR RRS RAS OE Dout Note: Previous 0 Previous 1 Previous 2 1 2 13 32 33 34 New 32 New 33 New 34 Add 'A + 1' 1 2 Add 'A' Previous data can be read out up to 32 WCK clock cycles after the write operation. 35 Datasheet Title Clear Write clear t WCC N WCK WCLR WWND t DS Din D(N - 1) D(N) Add(V, H) D(N + 1) t DH D0 D1 Add(0, 0) D2 t WCLS N+1 0 t WCLH 1 2 WRS WLRS WAS Note: The write address pointer is reset to (0, 0), and window mode is turned off if it was on. Read clear t RCC N RCK RCLR RWND t RAC Dout D(N - 1) D(N) Add(V, H) RRS RLRS RAS D(N + 1) D0 D1 Add(0, 0) D2 t RCLS N+1 0 t RCLH t OH 1 2 Note: The read address pointer is reset to (0, 0), and window mode is turned off if it was on. 36 Datasheet Title Window Scan Function Combined Window Scan Example In window scan mode, the destination address of a jump will be the first point in the window region, and line reset and reset operate as follows. Line reset: Resets to the left edge of the window on the next line. Reset: Resets to the first point in the window. In this mode, addresses are generated automatically internally, so this function is useful in applications that need to scan a window region. Also, completely independent window regions can be scanned by the read and write systems. Representative application examples are presented below. H (32 bit units) 0 0 (P, Q) (M, N) Window B (R, S) V Window A (P + p, Q + q) Window C (M + m, N + n) (R + r, S + s) 1024(1152) 319 37 Datasheet Title Case 1: Switching Between Normal and Window A Scan WWND (RWND) Mode 1st line WRS (RRS) WAS (RAS) WLRS (RLRS) Jump to (M, N) Window A 2nd line Last line in A 1st line Normal mode 2nd line Last line Window A 1st line 2nd line (M, N + 1) (M, N + n) Jump to (0, 0) (1, 0) Jump to (M, N) Case 2: Repeatedly Scanning Window A WWND (RWND) Mode 1st line Window A 2nd line Last line in A 1st line Window A 2nd line WRS (RRS) WAS (RAS) WLRS (RLRS) Jump to (M, N) (M, N + 1) (M, N + n) Jump to (M, N) (M, N + 1) 38 Datasheet Title Case 3: Switching from Window A Scan to Normal Scan to Window C Scan WWND (RWND) Mode 1 st line Window A 2nd line Last line in A 1st line Normal Window C 1st line 2nd line WRS (RRS) WAS (RAS) WLRS (RLRS) WCLR (RCLR) Jump to (M, N) (M, N + n) Jump to (0, (0, 1)0) New address setup: (P, Q) Jump to (R, S) New address setup: (R, S) (R, S + 1) Case 4: Switching from Window A Scan to Window B Scan to Window C Scan WWND (RWND) Mode Window A 1st line 2nd line Window B Last line in A 1st line Widnow C Last line in B 1st line 2nd line WRS (RRS) WAS (RAS) WLRS (RLRS) Jump to (M, N) (M, N + n) Jump to (P,Q + 1) (P, Q) (P,Q+q) Jump to (R, S + 1) (R, S) New address setup: (R, S) New address setup: (P, Q) 39 Datasheet Title Window Scan Timing Charts Window Jump (setup) * Write n WCK t WRS WRS WAS WWND D(N - 1) t WRS t WSS t WWDS D(N) Add '(X, Y)' t WSS t WWDS t WRH t WSH t WWDH t DS t DH D0 D1 Add '(M, N)' D2 n+1 0 t WCC 1 2 t DS t DH D(N + 1) Din Note: The value (M, N) is the address input during the write address setup cycle. Window Jump (setup) (cont) * Read n RCK t RRS RRS RAS RWND t RWDS Dout D(N) Add '(X, Y)' t RAC D(N + 1) D0 t OH D1 Add '(M, N)' D2 t RRS t RSS t RSS t RWDS t RRH t RSH t RWDH n+1 0 t RCC 1 2 Note: The value (M, N) is the address input during the read address setup cycle. 40 Datasheet Title Line Increment (in window mode) * Write n-1 WCK WLRS WRS Din WWND WCLR High t WLS t WLS t DS D(N) Don't Care High D(N - 1) Add(M, N + n) t WLH t DH D(0) D(1) D(2) Add(M + 1, N) n 0 t WCC 1 2 Note: The line address M is incremented and the horizontal address currently at N + n is reset to N. Line Increment (in window mode) (cont) * Read n-1 WCK RLRS RRS Dout t RLS High D(N - 1) Add(M,N + n) RWND RCLR Don't Care High D(N) t RLS t RLH t RAC D(0) t ROH D(1) Add(M + 1,N) D(2) n 0 t RCC 1 2 Note: The line address M is incremented and the horizontal address currently at N + n is reset to N. 41 Datasheet Title Line Hold (in window mode) * Write n-1 WCK WLRS WRS Din t WLS t WLS t t WRS WRS t DS D(N - 1) Add(M, N + n) WWND WCLR Don't Care High D(N) t WLH t WRH t DH D(0) D(1) Add(M, N) D(2) n 0 t WCC 1 2 Note: The line address M is held at its current value and the horizontal address currently at N + n is reset to N. * Read n -1 RCK RLRS RRS Dout t RLS t RLS n 0 t RCC 1 t RLH t RRH D(0) t RDH D(1) Add(M, N) D(2) 2 t RRS t RRS D(N - 1) Add(M, N + n) D(N) t RAC RWND RCLR Don't Care High Note: The line address M is held at its current value and the horizontal address currently at N + n is reset to N. 42 Datasheet Title Window Clear * Write t WCC N WCK t WRS WRS t WRS t WSS t WSS *1 N+1 0 t WRH t WSH 1 2 WAS WWND t WWDH t WWDS t DS t DH t DS t DH D(N - 1) D(N) Add'(X,Y)' D(N+1) D0 D1 Add'WA' D2 Din Note: 1. The write address is reset to (0, 0) when WAS is high. When WAS is low, the write address jumps to WA, and in any case, the write window is cleared. * Read t RCC N RCK t RRS RRS RAS RWND t RWDS Dout D(N) Add '(X, Y)' Note: 1. D(N + 1) t RRS t RSS t RSS t RRH t RRH *1 N+1 0 1 2 t RWDH t RAC D0 t OH D1 Add 'RA' D2 The read address is reset to (0, 0) when RAS is high. When RAS is low, the read address jumps to RA, and in any case, the read window is cleared. 43 Datasheet Title Clear * Write clear N WCK WCLR WWND t DS Din D(N - 1) D(N) Add(V, H) D(N+1) t DH D0 D1 Add(0, 0) D2 t WCLS t WCLS t WCLH N+1 0 t WCC 1 2 WRS WLRS WAS Note: The write address pointer is reset to (0, 0), and window mode is turned off if it was on. * Read clear N RCK RCLR RWND Dout D(N - 1) D(N) Add(V, H) RRS RLRS RAS D(N + 1) t RCLS t RCLS N+1 0 t RCC 1 2 t RCLH t OH t RAC D0 D1 Add(0, 0) D2 Note: The read address pointer is reset to (0, 0), and window mode is turned off if it was on. 44 Datasheet Title Reset to the Window Origin These figures show the timing charts for resetting the address pointer to the window origin address (M, N) during window scan mode execution * Write n WCK t WRS WRS WAS t WRS High t WWDS WWND t WWDS t DS t DH Din D(N - 1) D(N) Add '(M + m, N + n)' D(N+1) t DS t DH D0 D1 Add '(M, N)' D2 t WWDH t WRH n+1 0 t WCC 1 2 Note: The write address pointer is reset to the window origin address (M, N). * Read n RCK t RRS RRS RAS RWND Dout D(N) t RRS High t RWDS t RWDS n+1 0 t RCC 1 2 t RRH t RWDH t RAC t OH D0 D1 Add '(M, N)' D2 D(N + 1) Add '(M + m, N + n)' Note: The read address pointer is reset to the window origin address (M, N). 45 Datasheet Title Package Dimensions HM530281RTT Series (TTP-44DB) 18.41 18.81 Max 44 23 Unit: mm 1 0.30 0.10 0.80 0.21 M 22 10.16 1.005 Max 11.76 0.20 0 - 5 0.17 0.05 0.13 0.05 1.20 Max 0.10 0.80 0.50 0.10 46 Datasheet Title When using this document, keep the following in mind: 1. This document may, wholly or partially, be subject to change without notice. 2. All rights are reserved: No one is permitted to reproduce or duplicate, in any form, the whole or part of this document without Hitachi's permission. 3. Hitachi will not be held responsible for any damage to the user that may result from accidents or any other reasons during operation of the user's unit according to this document. 4. Circuitry and other examples described herein are meant merely to indicate the characteristics and performance of Hitachi's semiconductor products. Hitachi assumes no responsibility for any intellectual property claims or other problems that may result from applications based on the examples described herein. 5. No license is granted by implication or otherwise under any patents or other rights of any third party or Hitachi, Ltd. 6. MEDICAL APPLICATIONS: Hitachi's products are not authorized for use in MEDICAL APPLICATIONS without the written consent of the appropriate officer of Hitachi's sales company. Such use includes, but is not limited to, use in life support systems. Buyers of Hitachi's products are requested to notify the relevant Hitachi sales offices when planning to use the products in MEDICAL APPLICATIONS. Hitachi, Ltd. Semiconductor & IC Div. Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100, Japan Tel: Tokyo (03) 3270-2111 Fax: (03) 3270-5109 For further information write to: Hitachi America, Ltd. Semiconductor & IC Div. 2000 Sierra Point Parkway Brisbane, CA. 94005-1835 USA Tel: 415-589-8300 Fax: 415-583-4207 Hitachi Europe GmbH Electronic Components Group Continental Europe Dornacher Strae 3 D-85622 Feldkirchen Munchen Tel: 089-9 91 80-0 Fax: 089-9 29 30 00 Hitachi Europe Ltd. Electronic Components Div. Northern Europe Headquarters Whitebrook Park Lower Cookham Road Maidenhead Berkshire SL6 8YA United Kingdom Tel: 0628-585000 Fax: 0628-778322 Hitachi Asia Pte. Ltd. 16 Collyer Quay #20-00 Hitachi Tower Singapore 0104 Tel: 535-2100 Fax: 535-1533 Hitachi Asia (Hong Kong) Ltd. Unit 706, North Tower, World Finance Centre, Harbour City, Canton Road Tsim Sha Tsui, Kowloon Hong Kong Tel: 27359218 Fax: 27306071 47 |
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