E2L0021-17-Y1 ¡ Semiconductor MSM5416273 ¡ Semiconductor This version: Jan. 1998 MSM5416273 Previous version: Dec. 1996 262,144-Word ¥ 16-Bit Multiport DRAM DESCRIPTION The MSM5416273 is a 4-Mbit CMOS multiport DRAM composed of a 262,144-word by 16-bit dynamic RAM, and a 512-word by 16-bit SAM. Its RAM and SAM operate independently and asynchronously. It supports three types of operations: random access to RAM port, high speed serial access to SAM port, and bidirectional transfer of data between any selected row in the RAM port and the SAM port. In addition to the conventional multiport DRAM operating modes, the MSM5416273 features block write, flash write functions, extended page mode on the RAM port, a split data transfer capability, and programmable stops on the SAM port. The SAM port requires no refresh operation because it uses static CMOS flip-flops. FEATURES • Single power supply: 5 V ±10% • RAS only refresh • Full TTL compatibility • CAS before RAS refresh • Multiport organization • Hidden refresh RAM : 256K word ¥ 16 bits • Serial read/write SAM : 512 word ¥ 16 bits • 512 tap location • Extended page mode • Programmable stops • Write per bit • Bidirectional data transfer • Persistent write per bit • Split transfer • Byte read/write • Masked write transfer • Masked flash write • Refresh: 512 cycles/8 ms • Masked block write (8 columns) • Package: 64-pin 525 mil plastic SSOP (SSOP64-P-525-0.80-K) (Product : MSM5416273-xxGS-K) xx indicates speed rank. PRODUCT FAMILY Family Access Time Cycle Time Power Dissipation RAM SAM RAM SAM Operating Standby MSM5416273-50 50 ns 17 ns 110 ns 20 ns 180 mA 8 mA MSM5416273-60 60 ns 18 ns 120 ns 22 ns 170 mA 8 mA MSM5416273-70 70 ns 20 ns 140 ns 22 ns 160 mA 8 mA 1/40 ¡ Semiconductor MSM5416273 PIN CONFIGURATION (TOP VIEW) VCC TRG VSS SDQ0 DQ0 SDQ1 DQ1 VCC SDQ2 DQ2 SDQ3 DQ3 VSS SDQ4 DQ4 SDQ5 DQ5 VCC SDQ6 DQ6 SDQ7 DQ7 VSS CASL WE RAS A8 A7 A6 A5 A4 VCC 1 64 2 63 3 62 4 61 5 60 6 59 7 58 8 57 9 56 10 55 11 54 12 53 13 52 14 51 15 50 16 49 17 48 18 47 19 46 20 45 21 44 22 43 23 42 24 41 25 40 26 39 27 38 28 37 29 36 30 35 31 34 32 33 SC SE VSS SDQ15 DQ15 SDQ14 DQ14 VCC SDQ13 DQ13 SDQ12 DQ12 VSS SDQ11 DQ11 SDQ10 DQ10 VCC SDQ9 DQ9 SDQ8 DQ8 VSS DSF NC CASU QSF A0 A1 A2 A3 VSS 64-Pin Plastic SSOP Pin Name A0 - A8 Function Address Input Pin Name Function SC Serial Clock DQ0 - DQ15 RAM Inputs/Outputs SE SAM Port Enable SDQ0 - SDQ15 SAM Inputs/Outputs DSF Special Function Input RAS Row Address Strobe QSF Special Function Output CASL Column Address Strobe Lower VCC Power Supply (5 V) CASU Note: Column Address Strobe Upper VSS Ground (0 V) WE Write Enable NC No Connection TRG Transfer/Output Enable The same power supply voltage must be provided to every VCC pin, and the same GND voltage level must be provided to every VSS pin. 2/40 Block Write Control Column Mask Sense Amp. I/O Control Color Register Register RAM Input Buffer Mask Register A0 - A8 Refresh Counter Row Decoder Row Address Buffer 512 ¥ 512 ¥ 16 RAM ARRAY Gate Gate SAM SAM Serial Decoder SAM Address Buffer ¡ Semiconductor Column Decoder BLOCK DIAGRAM Column Address Buffer DQ 0 - 15 RAM Output Buffer Flash Write Control SAM Input Buffer RAS CASU / CASL SDQ 0 - 15 SAM Output Buffer Timing Generator TRG WE DSF SC SAM Address Counter QSF SE SE VCC VSS 3/40 MSM5416273 SAM Stop Control ¡ Semiconductor MSM5416273 ELECTRICAL CHARACTERISTICS Absolute Maximum Ratings (Note: 1) Parameter Symbol Condition Rating Unit Input Output Voltage VT Ta = 25°C –1.0 to 7.0 V Output Current IOS Ta = 25°C 50 mA Power Dissipation PD Topr Ta = 25°C 1 W Operating Temperature — 0 to 70 °C Storage Temperature Tstg — –55 to 150 °C Recommended Operating Conditions (Ta = 0°C to 70°C) (Note: 2) Parameter Symbol Min. Typ. Max. Unit Power Supply Voltage VCC 4.5 5.0 5.5 V Input High Voltage VIH 2.4 — 6.5 V Input Low Voltage VIL –1.0 — 0.8 V Capacitance (VCC = 5 V ±10%, f = 1 MHz, Ta = 25°C) Parameter Input Capacitance Input/Output Capacitance Output Capacitance Note: Symbol Min. Max. Unit Ci — 6 pF Cio — 7 pF Co(QSF) — 7 pF This parameter is periodically sampled and is not 100% tested. DC Characteristics 1 Symbol Condition Min. Max. Output "H" Level Voltage VOH IOH = –2 mA 2.4 — Output "L" Level Voltage VOL IOL = 2 mA — 0.4 Input Leakage Current ILI 0 £ VIN £ VCC All other pins not under test = 0 V –10 10 0 £ VOUT £ 5.5 V Output Disable –10 Parameter Output Leakage Current ILO Unit V mA 10 4/40 ¡ Semiconductor MSM5416273 DC Characteristics 2 (VCC = 5 V ±10%, Ta = 0°C to 70°C) Item (RAM) Operating Current (RAS, CAS Cycling, tRC = tRC min.) Standby Current (RAS, CAS = VIH) RAS Only Refresh Current (RAS Cycling, CAS = VIH, tRC = tRC min.) Page Mode Current (RAS = VIL, CAS Cycling, tPC = tPC min.) CAS before RAS Refresh Current (RAS Cycling, CAS before RAS, tRC = tRC min.) Data Transfer Current (RAS, CAS Cycling, tRC = tRC min.) Flash Write Current (RAS, CAS Cycling, tRC = tRC min.) Block Write Current (RAS, CAS Cycling, tRC = tRC min.) -50 -60 -70 SAM Symbol Standby ICC1 140 130 120 3, 4 17 Max. Max. Max. Active ICC1A 180 170 160 Standby ICC2 8 8 8 Unit Note Active ICC2A 60 55 55 3, 4 Standby ICC3 140 130 120 3, 4 Active ICC3A 180 170 160 17 Standby ICC4 150 140 130 3, 4 Active ICC4A 200 190 180 Standby ICC5 120 110 100 Active ICC5A 160 150 140 3, 4 Standby ICC6 130 120 110 3, 4 Active ICC6A 170 160 150 17 Standby ICC7 130 120 110 3, 4 Active ICC7A 170 160 150 3, 4 Standby ICC8 130 120 110 3, 4 Active ICC8A 170 160 150 3, 4 mA 18 3, 4 5/40 ¡ Semiconductor MSM5416273 AC Characteristics (1/3) Parameter Symbol -50 -60 Min. Max. Min. Max. Min. Max. tRC 84 — 104 Read Modify Write Cycle tRWC 135 — Fast Page Mode Cycle Time tHPC 20 — Random Read or Write Cycle Time Fast Page Mode Read Modify Write Cycle Time -70 — Unit Note — 124 ns 140 — 170 — ns 25 — 30 — ns tPRWC 66 — 70 — 74 — ns Access Time from RAS tRAC — 50 — 60 — 70 ns 8, 14 Access Time from Column Address tAA — 25 — 30 — 35 ns 8, 14 Access Time from CAS tCAC — 15 — 15 — 20 ns 8, 15 Access Time from CAS Precharge tCPA — 30 — 35 — 40 ns 8, 15 Output Buffer Turn-off Delay tOFF 0 12 0 15 0 17 ns 10 tT 2 35 2 35 2 35 ns 7 Transition Time (Rise and Fall) RAS Precharge Time tRP 30 — 40 — 50 — ns RAS Pulse Width tRAS 50 10k 60 10k 70 10k ns RAS Pulse Width (Fast Page Mode Only) tRASP 50 100k 60 100k 70 100k ns RAS Hold Time tRSH 15 — 15 — 20 — ns CAS Hold Time tCSH 45 — 45 — 55 — ns CAS Pulse Width tCAS 10 10k 10 10k 10 10k ns RAS to CAS Delay Time tRCD 15 35 15 42 15 50 ns 14 RAS to Column Address Delay Time tRAD 12 25 12 30 12 35 ns 14 Column Address to RAS Lead Time tRAL 25 — 30 — 35 — ns CAS to RAS Precharge Time tCRP 5 — 5 — 10 — ns CAS Precharge Time (Fast Page Mode) tCP 6 — 10 — 10 — ns Row Address Set-up Time tASR 0 — 0 — 0 — ns Row Address Hold Time tRAH 8 — 10 — 10 — ns Column Address Set-up Time tASC 0 — 0 — 0 — ns Column Address Hold Time tCAH 8 — 10 — 10 — ns Column Address Hold Time referenced to RAS tAR 40 — 50 — 55 — ns Read Command Set-up Time tRCS 0 — 0 — 0 — ns Read Command Hold Time tRCH 0 — 0 — 0 — ns 11 Read Command Hold Time referenced to RAS tRRH 0 — 0 — 0 — ns 11 CAS "H" to RAS "H" Lead Time tCRL 0 — 0 — 0 — ns RAS "H" to CAS "H" Lead Time tRCL 0 — 0 — 0 — ns Data Output Hold after CAS Low tCOH 3 — 3 — 3 — ns 19 Write Command Set-up Time tWCS 0 — 0 — 0 — ns 13 Write Command Hold Time tWCH 8 — 10 — 10 — ns Write Command Hold Time referenced to RAS tWCR 40 — 50 — 55 — ns Write Command Pulse Width tWP 8 — 10 — 10 — ns Write Command to RAS Lead Time tRWL 12 — 15 — 15 — ns Write Command to CAS Lead Time tCWL 12 — 15 — 15 — ns 6/40 ¡ Semiconductor MSM5416273 AC Characteristics (2/3) Parameter Data Set-up Time Symbol tDS -50 -60 -70 Min. Max. Min. Max. Min. Max. 0 — 0 — 0 Unit Note — ns 12 12 Data Hold Time tDH 8 — 10 — 12 — ns Data Hold Time referenced to RAS tDHR 40 — 50 — 55 — ns RAS to WE Delay Time tRWD 70 — 80 — 90 — ns 13 Column Address to WE Delay Time tAWD 45 — 50 — 55 — ns 13 13 CAS to WE Delay Time tCWD 30 — 35 — 40 — ns Data to CAS Delay Time tDZC 0 — 0 — 0 — ns Data to TRG Delay Time tDZO 0 — 0 — 0 — ns Access Time from TRG tOEA — 15 — 15 — 20 ns Output Buffer Turn-off Delay from TRG tOEZ 0 12 0 15 0 15 ns TRG Command Hold Time tOEH 8 — 10 — 10 — ns RAS Hold Time referenced to TRG tROH 10 — 10 — 15 — ns CAS Set-up Time for CAS before RAS Cycle tCSR 5 — 5 — 5 — ns CAS Hold Time for CAS before RAS Cycle tCHR 8 — 10 — 10 — ns RAS Precharge to CAS Active Time tRPC 0 — 0 — 0 — ns Refresh Period tREF — 8 — 8 — 8 ms WE Set-up Time tWSR 0 — 0 — 0 — ns WE Hold Time tRWH 8 — 10 — 10 — ns DSF Set-up Time referenced to RAS tFSR 0 — 0 — 0 — ns DSF Hold Time referenced to RAS (1) tRFH 8 — 10 — 10 — ns DSF Hold Time referenced to RAS (2) tFHR 40 — 50 — 55 — ns DSF Set-up Time referenced to CAS tFSC 0 — 0 — 0 — ns DSF Hold Time referenced to CAS tCFH 8 — 10 — 10 — ns Write Per Bit Mask Data Set-up Time tMS 0 — 0 — 0 — ns Write Per Bit Mask Data Hold Time tMH 8 — 10 — 10 — ns TRG High Set-up Time tTHS 0 — 0 — 0 — ns TRG High Hold Time tTHH 8 — 10 — 10 — ns TRG Low Set-up Time tTLS 0 — 0 — 0 — ns TRG Low Hold Time tTLH 8 10k 10 10k 10 10k ns TRG Low Hold Time referenced to RAS tRTH 40 10k 50 10k 60 10k ns TRG Low Hold Time referenced to Column Address tATH 20 — 20 — 25 — ns TRG Low Hold Time referenced to CAS tCTH 15 — 15 — 20 — ns 7/40 ¡ Semiconductor MSM5416273 AC Characteristics (3/3) Parameter Symbol -50 -60 -70 Min. Max. Min. Max. Min. Max. Unit Note TRG to RAS Precharge Time tTRP 40 — 40 — 50 — ns TRG Precharge Time tTP 15 — 20 — 20 — ns RAS to First SC Delay Time (Read Transfer) tRSD 50 — 60 — 70 — ns Column Address to First SC Delay Time tASD 25 — 30 — 35 — ns CAS to First SC Delay Time (Read Transfer) tCSD 20 — 20 — 20 — ns Last SC to TRG Lead Time tTSL 5 — 5 — 5 — ns TRG to First SC Delay Time (Read Transfer) tTSD 10 — 10 — 10 — ns Last SC to RAS Set-up Time (Serial Input) tSRS 20 — 20 — 25 — ns Serial Output Buffer Turn-off Delay from RAS tSDZ 10 30 10 30 10 40 ns SC Cycle Time tSCC 18 — 18 — 20 — ns SC Pulse Width (SC High Time) tSC 5 — 5 — 5 — ns SC Precharge Time (SC Low Time) tSCP 5 — 5 — 5 — ns Access Time from SC tSCA — 15 — 15 — 17 ns 9 Serial Output Hold Time from SC tSOH 3 — 3 — 5 — ns 19 Access Time from SE tSEA — 15 — 15 — 17 ns 9 SE Pulse Width tSE 10 — 10 — 10 — ns SE Precharge Time tSEP 10 — 10 — 10 — ns Serial Output Buffer Turn-off Delay from SE tSEZ 0 14 0 15 0 15 ns Split Transfer Set-up Time tSTS 20 — 20 — 25 — ns Split Transfer Hold Time tSTH 20 — 20 — 25 — ns SC-QSF Delay Time tSQD — 20 — 20 — 25 ns TRG-QSF Delay Time tTQD — 20 — 20 — 25 ns CAS-QSF Delay Time tCQD — 30 — 30 — 35 ns RAS-QSF Delay Time tRQD — 65 — 70 — 75 ns RAS to Serial Input Delay Time tSDD 30 — 30 — 40 — ns Serial Input Set-up Time tSDS 0 — 0 — 0 — ns Serial Input Hold Time tSDH 8 — 10 — 10 — ns Serial Input to SE Delay Time tSZE 0 — 0 — 0 — ns Serial Input to First SC Delay Time tSZS 0 — 0 — 0 — ns Serial Write Enable Set-up Time tSWS 0 — 0 — 0 — ns Serial Write Enable Hold Time tSWH 8 — 10 — 10 — ns Serial Write Disable Set-up Time tSWIS 0 — 0 — 0 — ns Serial Write Disable Hold Time tSWIH 8 — 10 — 10 — ns 10 10 8/40 ¡ Semiconductor Notes: MSM5416273 1. Exposure beyond the "Absolute Maximum Ratings" may cause permanent damage to the device. 2. All voltages are referenced to VSS. 3. These parameters depend on the cycle rate. 4. These parameters depend on output loading. Specified values are obtained with the output open. 5. An initial pause of 200 ms is required after power up followed by any 8 RAS cycles (TRG = "high") and any 8 SC cycles before proper device operation is achieved. In the case of using an internal refresh counter, a minimum of 8 CAS before RAS cycles instead of 8 RAS cycles are required. 6. AC measurements assume tT = 5 ns. 7. VIH (Min.) and VIL (Max.) are reference levels for measuring timing of input signals. Also, transition times are measured between VIH and VIL. 8. RAM port outputs are measured with a load equivalent to 1 TTL load and 50 pF. DOUT reference levels : VOH/VOL = 2.0 V/0.8 V. 9. SAM port outputs are measured with a load equivalent to 1 TTL load and 30 pF. DOUT reference levels : VOH/VOL = 2.0 V/0.8 V. 10. tOFF (Max.), tOEZ (Max.), tSDZ (Max.) and tSEZ (Max.) define the time at which the outputs achieve the open circuit condition, and are not referenced to output voltage levels. This parameter is sampled and not 100% tested. 11. Either tRCH or tRRH must be satisfied for a read cycle. 12. These parameters are referenced to CAS leading edge of early write cycles, and to WE leading edge in TRG controlled write cycles and read modify write cycles. 13. tWCS, tRWD, tCWD and tAWD are not restrictive operating parameters. They are included in the data sheet as electrical characteristics only. If tWCS ≥ tWCS (Min.), the cycle is an early write cycle, and the data out pin will remain open circuit throughout the entire cycle; If tRWD ≥ tRWD (Min.), tCWD ≥ tCWD (Min.) and tAWD ≥ tAWD (Min.), the cycle is a read modify write cycle, and the data out will contain data read from the selected cell; If neither of the above sets of conditions are satisfied, the condition of the data out is indeterminate. 14. Operation within the tRCD (Max.) limit ensures that tRAC (Max.) can be met. tRCD (Max.) is specified as a reference point only: If tRCD is greater than the specified tRCD (Max.) limit, then access time is controlled by tCAC. 15. Operation within the tRAD (Max.) limit ensures that tRAC (Max.) can be met. tRAD (Max.) is specified as a reference point only: If tRAD is greater than the specified tRAD (Max.) limit, then access time is controlled by tAA. 16. Input levels at the AC testing are 3.0 V/0 V. 17. Address (A0 - A8) may be changed two times or less while RAS = VIL. 18. Address (A0 - A8) may be changed once or less while CAS = VIH and RAS = VIL. 19. This is guaranteed by design. (tSOH/tCOH = tSCA/tCAC - output transition time) This parameter is not 100% tested. 9/40 ¡ Semiconductor MSM5416273 TIMING WAVEFORM Read Cycle (Outputs Controlled by RAS) tRC tRAS tRP RAS tCSH tCRP tRSH tRCD tCAS CASL tCSH tCRP tRSH tCAS tRCD , , , , CASU tCRL tAR tRAD tASR Address tRAL tASC tRAH Row tCAH Column tFHR tFSR tRFH tFSC tCFH DSF tRCS tRCH WE tRRH tCAC tOFF tAA Open DQ0 - 7 Valid Data tRAC Open DQ8 - 15 Valid Data tROH tTHS tTHH tOEA tOEZ TRG "H" or "L" 10/40 ¡ Semiconductor MSM5416273 Read Cycle (Outputs Controlled by CAS) tRC tRAS tRP RAS , ,, tCSH tCRP CASL tRSH tRCD tCAS tRCL tCSH tCRP CASU tRSH tCAS tRCD tRCL tAR tRAD tASR Address tRAL tASC tRAH Row tCAH Column tFHR tFSR DSF tRFH tFSC tCFH tRCS WE tRRH tRCH tCAC tOFF tAA DQ0 - 7 Open Valid Data tRAC DQ8 - 15 Open Valid Data tROH tTHS TRG tTHH tOEA tOEZ "H" or "L" 11/40 ¡ Semiconductor MSM5416273 Extended Page Mode Read Cycle tRASP tRP , ,, RAS tCSH tCRP tHPC tRCD tCAS tCP tRSH tCAS tCP tCAS CASL tCSH tCRP tHPC tRCD CASU tCAS tCP tRSH tCAS tCP tAR tRAD tASR Address tCAS tRAL tRAH tASC Row tCAH tASC Column tCAH tASC Column tCAH Column tFHR tFSR tRFH tFSC tCFH tFSC tCFH tFSC tCFH DSF tRCS tRCS tRCH tRCS tRRH tRCH WE tCAC tAA Open DQ0 - 7 Open tTHS tTHH tCAC tCOH tCOH Valid Data tRAC DQ8 - 15 tCAC Valid Data tAA tAA tCPA tCPA Valid Data tOEA Valid Data Valid Data tOEZ Valid Data tRCH tOFF Valid Data Valid Data tOEA TRG "H" or "L" 12/40 ¡ Semiconductor MSM5416273 Write Cycle Function Table RAS Falling Edge Code CAS Falling Edge A C D B E DSF WE DQ DSF DQ Function RWM 0 0 Write Mask 0 Valid Data BWM 0 0 Write Mask 1 Column Mask Masked Block Write (New/Old) FWM 1 0 Write Mask X X Masked Flash Write (New/Old) RW 0 1 X 0 Valid Data BW 0 1 X 1 Column Mask Block Write LMR 1 1 X 0 Write Mask Data Load Mask Register LCR 1 1 X 1 Color Data Load Color Register Masked Write (New/Old) Normal Write WRITE MASK DATA: "Low" = Mask, "High" = No Mask Column Mask Data Lower Byte Upper Byte DQ0 - 15 Column Mask Data DQ0 Column 0 (A0 = 0, A1 = 0, A2 = 0) DQ1 Column 1 (A0 = 1, A1 = 0, A2 = 0) DQ2 Column 2 (A0 = 0, A1 = 1, A2 = 0) DQ3 Column 3 (A0 = 1, A1 = 1, A2 = 0) Low : Mask DQ4 Column 4 (A0 = 0, A1 = 0, A2 = 1) High : No Mask DQ5 Column 5 (A0 = 1, A1 = 0, A2 = 1) DQ6 Column 6 (A0 = 0, A1 = 1, A2 = 1) DQ7 Column 7 (A0 = 1, A1 = 1, A2 = 1) DQ8 Column 0 (A0 = 0, A1 = 0, A2 = 0) DQ9 Column 1 (A0 = 1, A1 = 0, A2 = 0) DQ10 Column 2 (A0 = 0, A1 = 1, A2 = 0) DQ11 Column 3 (A0 = 1, A1 = 1, A2 = 0) Low : Mask DQ12 Column 4 (A0 = 0, A1 = 0, A2 = 1) High : No Mask DQ13 Column 5 (A0 = 1, A1 = 0, A2 = 1) DQ14 Column 6 (A0 = 0, A1 = 1, A2 = 1) DQ15 Column 7 (A0 = 1, A1 = 1, A2 = 1) 13/40 ¡ Semiconductor MSM5416273 Early Write Cycle tRC tRAS tRP RAS tCSH , ,, , ,, tCRP CASL tRSH tCAS tRCD tCSH tCRP CASU tRSH tCAS tRCD tAR tRAD tRAH tASR Address tRAL tASC Row tCAH Column tFHR tRFH tFSR DSF tFSC A tCFH B tCWL WE tRWL tRWH tWSR tWP C tWCR tWCS tMS DQ0 - 7 tMH tDHR tDS tDH E D tTHS TRG tDHR tDS D tMS DQ8 - 15 tMH tWCH tDH E tTHH "H" or "L" 14/40 ¡ Semiconductor MSM5416273 Late Write Cycle tRC tRAS tRP RAS tCSH tCRP CASL tRSH tCAS tRCD , ,, , , ,, tCSH tCRP CASU tRSH tCAS tRCD tAR tRAD tRAH tASR Address tRAL tASC Row tCAH Column tFHR tRFH tFSR DSF tFSC A tCFH B tCWL tRWH tWSR WE tRWL tRCS tWP C tWCR tDHR tMH tMS DQ0 - 7 tDS D tDH E tDHR tMH tMS DQ8 - 15 D tTHS TRG tDS tDH E tOEH "H" or "L" 15/40 ¡ Semiconductor MSM5416273 Read Modify Write Cycle tRWC tRAS tRP RAS tCSH tCRP CASL tRSH tCAS tRCD , ,, ,, ,, tCSH tCRP CASU tRSH tRCD tCAS tAR tRAD Address tRAL tRAH tASR tASC Row Column tAWD tFHR tRFH tFSR DSF tCAH tFSC A tCFH B tCWL tRWH tWSR WE tRCS tCWD tRWL tWP C tRWD tCAC tMH tMS DQ0 - 7 tDS Valid Data D tMH tMS DQ8 - 15 tRAC tDZC tDH E tDS Valid Data D tDH E tDZO tTHS TRG tTHH tOEA tOEZ tOEH "H" or "L" 16/40 ¡ Semiconductor MSM5416273 Fast Page Mode Early Write Cycle tRASP tRP RAS tCSH tCRP tHPC tCAS tRCD tCP tCAS tRSH tCP tCAS CASL tCSH tCRP tHPC tCAS tRCD tCP tCAS tRSH tCP tCAS CASU tAR tRAL tRAD ,, , tASR tRAH Address tASC Row tCAH tASC Column tCAH tASC Column tCAH Column tFHR tFSR DSF tRFH tFSC tCFH A tFSC B tCFH tFSC B tCWL tCFH B tCWL tCWL tWSR tRWH tWP WE tWP tWP C tMS DQ0 - 7 tMH tDS D tMS DQ8 - 15 tDS E tMH D tTHS tDH tDS tDS E tDH E tDH tDS E tDH E tDH tDS tDH E tTHH TRG "H" or "L" 17/40 ¡ Semiconductor MSM5416273 Fast Page Mode Read Modify Write Cycle tRASP tRP RAS tCSH tCRP tPRWC tCAS tRCD tCP tRSH tCAS tCP tCAS CASL tCSH tCRP tPRWC tCAS tRCD CASU tCP tRSH tCAS tCP tCAS tAR tRAL tRAD , , , tASR Address tRAH tASC tASC tCAH Row Column tASC tCAH Column tCAH Column tFHR tFSR DSF tRFH A B tWSR WE tFSC tFSC tCFH B tCWL tAWD tRWH tFSC tCFH tCFH B tCWL tAWD tCWL tAWD C tWP tWP tCWD tCWD tRCS tCAC DQ0 - 7 tMH tMS DQ8 - 15 tDH tDH tDH tAA tDS tDS Out In Out In Out In Out In Out In Out In tMH D tOEZ tTHS tCAC tAA tDS D tCWD tCAC tAA tMS tWP tTHH tOEA tOEZ tOEA tOEZ tOEA TRG "H" or "L" 18/40 ¡ Semiconductor MSM5416273 RAS Only Refresh Cycle tRC tRAS RAS tRP , ,,, , ,,, tCRP CASL/U tASR Address WE DQ0 - 15 tRFH Open tTHS TRG tRAH Row tFSR DSF tRPC tTHH "H" or "L" 19/40 ¡ Semiconductor MSM5416273 CAS before RAS Refresh Cycle tRC tRP RAS tCSR tCHR tRAH A tRFH tFSR DSF B tRWH tWSR WE tRPC Inhibit Falling Transition tASR Address tRP ,,,, tRPC CASL/U tRAS C tOFF DQ0 - 15 TRG Open "H" or "L" Note: The type of CBR operations are determined by the logic states of "A", "B" and "C". CBR Cycle Function Table Code RAS Falling Edge Function A B C CBRR X 0 1 CBR Refresh (Reset All Options) CBRS STOP Address 1 0 CBR Refresh (Set STOP Address) CBRN X 1 1 CBR Refresh (No Reset Options) 20/40 ¡ Semiconductor MSM5416273 Hidden Refresh Cycle tRC tRAS RAS , , , ,, tCRP CASL/U tRCD tRSH tAR tRAD tASR Address tRAS tRP tRAH tCHR tRAL tASC Row tASR tCAH Column tRAH A tFHR tFSR DSF tRFH tFSC tFSR tCFH B tWSR tRCS WE tRFH tRWH C tRRH tCAC tOFF tAA DQ0 - 15 Open Valid Data tRAC tTHS TRG tTHH tOEA tOEZ "H" or "L" Note: The type of CBR operations are determined by the logic states of "A", "B" and "C". 21/40 ¡ Semiconductor MSM5416273 Read Transfer 1 tRC tRAS RAS tRP , ,,, , tCSH tRSH tCAS tRCD CASL/U tAR tRAD Row tFSR DSF tASC tRAH tASR Address tRAL tCAH SAM Start tRFH tWSR tRWH WE tASD tCSD DQ0 - 15 tRSD Open tTRP tTLS TRG tTLH tTP tSC tTSD tSCP tSRS SC Note 2 tSIS SDQ0 - 15 tSCA tSZS tSIH tSCA tSOH Data Out Din tRQD QSF tSCC tSC tCQD Note 3 tTQD Note 3 "H" or "L" Note 1: SE = "L" Note 2: There must be no rising transitions Note 3: QSF = "L"-- Lower SAM (0 - 255) is active QSF = "H"-- Upper SAM (256 - 511) is active 22/40 ¡ Semiconductor MSM5416273 Read Transfer 2 (Real Time Read Transfer) tRC tRAS RAS tRP , ,,, tCSH tRSH tCAS tRCD CASL/U tAR tRAD Address Row tFSR DSF tASC tRAH tASR tRAL tCAH SAM Start tRFH tWSR tRWH WE tCTH tATH DQ0 - 15 Open tTRP tTLS TRG tTP tRTH tSCC tSCP SC tTSL tSC tTSD tSCA tSOH SDQ0 - 15 tSCA tSOH Data Out Data Out Data Out Data Out tTQD QSF Note 2 Note 2 "H" or "L" Note 1: SE = "L" Note 2: QSF = "L"-- Lower SAM (0 - 255) is active QSF = "H"-- Upper SAM (256 - 511) is active 23/40 ¡ Semiconductor MSM5416273 Split Read Transfer tRC tRAS RAS tRP , ,,, tCSH tRSH tRCD CASL/U tAR tRAD tASR Address tRAH tRAL tASC Row tFSR DSF tCAS tCAH SAM Start Sj tRFH tWSR tRWH WE tCTH tATH DQ0 - 15 tTLS TRG tTLH tSCC tSCP tSC tSTS SC SDQ0 - 15 Open tRTH STOP i tSCA tSOH Data Out Si tSCA tSOH Data Out Data Out STOP j-1 STOP j Data Out Data Out tSQD QSF Note 2 Sj Data Out tSQD Note 2 Note 2 "H" or "L" Note 1: SE = "L" Note 2: QSF = "L"-- Lower SAM (0 - 255) is active QSF = "H"-- Upper SAM (256 - 511) is active Note 3: Si is the SAM start address in before SRT Note 4: STOP i and STOP j are programmable stop addresses 24/40 ¡ Semiconductor MSM5416273 Masked Write Transfer tRC tRAS RAS tRP , ,,, tCSH tRSH tCAS tRCD CASL/U tAR tRAD tASR Address Row tFSR DSF tRAL tASC tRAH tCAH SAM Start tRFH tWSR tRWH WE tMS DQ0 - 15 tCSD tMH Open Mask Data tRSD tTLS TRG tTLH tSRS tSCC tSC SC tSCP tSC Note 2 tSDZ tSDS tSOH SDQ0 - 15 Dout Dout tSDH tSDS Data In tSDD tSDH Data In tCQD tRQD QSF Note 3 Note 3 "H" or "L" Note 1: SE = "L" Note 2: There must be no rising transitions Note 3: QSF = "L"-- Lower SAM (0 - 255) is active QSF = "H"-- Upper SAM (256 - 511) is active 25/40 ¡ Semiconductor MSM5416273 Masked Split Write Transfer tRC tRAS RAS tRP , ,,, tCSH tRSH tCAS tRCD CASL/U tAR tRAD tASR Address Row tFSR DSF tRAL tASC tRAH tCAH SAM Start Sj tRFH tWSR tRWH WE tMS DQ0 - 15 Mask Data tTLS TRG tCTH tATH tMH tTLH tSCC tSCP tSC tSTS SC STOP i Si tSDS SDQ0 - 15 Data In Open tRTH tSDH Data In STOP j-1 tSDS Note 2 Sj tSDH Data In Data In Data In Data In tSQD tSQD QSF STOP j Note 2 Note 2 "H" or "L" Note 1: SE = "L" Note 2: QSF = "L"-- Lower SAM (0 - 255) is active QSF = "H"-- Upper SAM (256 - 511) is active Note 3: Si is the SAM start address in before SWT Note 4: STOP i and STOP j are programmable stop addresses 26/40 ¡ Semiconductor MSM5416273 Serial Read Cycle tSEP SE tSCC tSC SC tSCA tSCP tSOH SDQ0 - 15 tSEA tSEZ Data Out Data tSCA tSCA tSOH tSOH Data Data Out Data Out Serial Write Cycle tSEP SE tSCC tSC SC tSWH Data In tSWIH tSWS tSCP tSDS SDQ0 - 15 tSWIS tSDH Data In tSZE tSDS tSDH Data In Data In "H" or "L" 27/40 ¡ Semiconductor MSM5416273 PIN FUNCTIONS Address Input: A0 - A8 The 18 address bits decode 16 bits of the 4,194,304 locations in the MSM5416273 memory array. The address bits are multiplexed to 9 address input pins (A0 - A8) as standard DRAM. 9 row address bits are latched at the falling edge of RAS. The following 9 column address bits are latched at the falling edge of CAS. Row Address Strobe: RAS RAS is a basic RAM control signal. The RAM port is in standby mode when the RAS level is "high". As the standard DRAM’s RAS signal function, RAS is the control input that latches the row address bits, and a random access cycle begins at the falling edge of RAS. In addition to the conventional RAS signal function, the level of the input signals CAS, TRG, WE and DSF at the falling edge of RAS, determines the MSM5416273 operation mode. Column Address Strobe: CASL and CASU As the standard DRAM’s CAS signal function, CAS is the control input signal that latches the column address input, and the state of the special function input DSF to select in conjunction with the RAS control, either read/write operations or the special block write feature on the RAM port when the DSF is held "low" at the falling edge of RAS. CAS also acts as a RAM port output enable signal. Data Transfer/Output Enable: TRG TRG is also a control input signal having multiple functions. As the standard DRAM’s OE signal function, TRG is used as an output enable control when TRG is "high" at the falling edge of RAS. In addition to the conventional OE signal function, a data transfer operation is started between the RAM port and the SAM port when TRG is "low" at the falling edge of RAS. Write Per Bit/Write Enable: WE WE is control input signal having multiple functions. As the standard DRAM’s WE signal function, this is used to write data into the memory on the RAM port when WE is "high" at the falling edge of RAS. In addition to the conventional WE signal function, the WE determines the write-per-bit function, when WE is "low" at the falling edge of RAS during RAM port operations. The WE also determines the direction of data transfer between the RAM and SAM. When the WE is "high" at the falling edge of RAS, the data is transferred from RAM to SAM (read transfer). When the WE is "low" at the falling edge of RAS, the data is transferred SAM to RAM (write transfer). 28/40 ¡ Semiconductor MSM5416273 Write Mask Data/Data Input and Output: DQ0 - DQ15 In conventional write-per bit mode, the DQ pins function as mask data at the falling edge of RAS. Data is written only to high DQ pins. Data on low DQ pins is masked and internal data is retained. After that, they function as input/output pins similar to a standard DRAM. In persistent write-per-bit mode, DQ pins do not consider the falling edge of RAS. The mask data is determined in the mask register load cycle. Serial Clock: SC SC is a main serial cycle control input signal. All operations of the SAM port are synchronized with the serial clock SC. Data is shifted in or out of the SAM registers at the rising edge of SC. In a serial read cycle, the output data becomes valid on the SDQ pins after the maximum specified serial access time tSCA from the rising edge of SC. In a serial write cycle, data on SDQ pins at the rising edge of SC are fetched into the SAM register. Serial Enable: SE The SE is a serial access enable control and serial read/write control signal. In a serial read cycle, SE is used as an output control. In a serial write cycle, SE is used as a write enable control. When SE is "high", serial access is disabled. However, the serial address pointer location is still incremented when SC is clocked even when SE is "high". Special Function Input: DSF The DSF is latched at the falling edge of RAS and CAS. It allows for the selection of several RAM ports and transfer operating modes. In addition to the conventional multiport DRAM, the special functions consisting of flash write, block write, load/read color register, and split read/write transfer can be invoked. Special Function Output: QSF QSF is an output signal, which during split register mode indicates which half of the split SAM is being accessed. QSF "low" indicates that the lower split SAM (0 - 255) is being accessed. QSF "high" indicates that the upper SAM (256 - 511) is being accessed. QSF is enabled by SE. When SE is "high", QSF is in high impedance. Serial Input/Output: SDQ0 - SDQ15 Serial input/output mode is determined by the most recent read or write transfer cycle. When a read transfer cycle is performed, the SAM port is in the output mode. When a write or pseudo write transfer cycle is performed, the SAM port is switched from output mode to input mode. 29/40 ¡ Semiconductor MSM5416273 OPERATION MODES Table-1 shows the function truth table for a listing of all available RAM ports, and transfer operations of the MSM5416273. The RAM port and data transfer operations are determined by the state of CAS, TRG, WE and DSF at the falling edge of RAS, and by the level of DSF at the falling edge of CAS. Table-1. Function Truth Table RASØ Code CBRR CASØ Address W/IO CAS TRG WE DSF DSF RASØ CASØ RASØ 0 * 1 0 — * * * CAS /WEØ * Write Pers. Register Mask W.M. WM Color — Reset Reset — Function CBR Refresh (Register Reset) CBR Refresh CBRS 0 * 0 1 — STOP * * * — — — — CBRN 0 * 1 1 — * * * — — — — CBR Refresh (No Reset) ROR 1 1 * 0 — Row — * — — — — — RAS Only Refresh MWT 1 0 0 0 * Row TAP WM1 * Yes — Masked Write Transfer MSWT 1 0 0 1 * Row TAP WM1 * Yes RT 1 0 1 0 * Row TAP * * SRT 1 0 1 1 * Row TAP * * RWM 1 1 0 0 0 Row Column WM1 Din,Dout Yes BWM 1 1 0 0 1 Row FWM 1 1 0 1 * Row RW 1 1 1 0 0 Row Column BW LMR LCR Notes: 1 1 1 1 1 1 1 1 1 0 1 1 1 0 1 * Row Row Row Column A3c - 8c * Column A3c - 8c * * WM1 Column Select WM1 — * * * * Din,Dout Column Select Mask Data Color Data No/ Load Yes Use No/ Load — (Stop Register Set) Masked Split Yes Use — — — — Read Transfer — — — — Split Read Transfer Yes Yes No/ Load Yes Use No/ Load Yes Use No/ Load — Use Use Yes Use No No — — No No — Use — Set Load — — — — Load Write Transfer Read/Write (New/Old Mask) Masked Block Write (New/Old) Masked Flash Write (New/Old) Read/Write (No Mask) Block Write (No Mask) Load Mask Register (Old Mask Set) Load Color Register 1. With CBRS and SAM operations use stop register. 2. After LMR, RWM, BWM, FWM and MSWT, use the old mask which can be reset by CBRR. 30/40 ¡ Semiconductor MSM5416273 If the DSF is "high" at the falling edge of RAS, special functions such as split transfer, flash write, load mask register, load color register, CBRS and CBRN can be invoked. If the DSF is "low" at the falling edge of RAS and "high" at the falling edge of CAS, the block write feature can be invoked. RAM PORT OPERATION Extended RAM Read Cycle: RAS falling edge --- TRG = CAS = "H", DSF = "L" CAS falling edge --- DSF = "L" The MSM5416273 offers an accelerated page mode cycle (EXTENDED PAGE MODE) by eliminating output disable from CAS "high", and it allows CAS precharge time (tCP) to occur without the output data becoming invalid. This new data out operates (Extended data out) as any RAM read or Page Mode Read, except data will be held valid after CAS goes "high", as long as RAS is "low". Byte read occurs if either CASL or CASU falls during the cycle. RAM Write Cycle: RAS falling edge --- TRG = CAS = "H", DSF = "L" CAS falling edge --- DSF = "L" 1) Write cycle with no mask: RAS falling edge -- WE = "H" If WE is set "low" at the falling edge of CAS after RAS goes "low", a write cycle is excuted. If WE is set "low" before the CAS falling edge, this cycle becomes an early write cycle, and all DQ pins attain high impedance. If WE is "low" when CAS goes "low", the write affects only those corresponding 8 bits with the latched data. If WE is set "low" after the CAS falling edge, this cycle becomes a late write cycle, and all 16 data are latched on the falling edge of WE. Byte write occurs if either CASL or CASU falls during the cycle. DQ pins don't achieve high impedance in this cycle, so data should be entered with TRG in "high". 2) Write cycle with mask: RAS falling edge -- WE = "L" If WE is set "low" at the falling edge of RAS, two modes of mask write can be invoked. #1 In new mask mode mask data is loaded and used. The mask data on DQ0 - DQ15 is latched into the write mask register at the falling edge of RAS. When the mask data is low, writing is inhibited into the RAM and the mask data is high, data is written into the RAM. This mask data is in effect during the RAS cycle. In page mode cycle the mask data is retained during page access. #2 If a load mask register cycle (LMR) has been performed, the mask data is not loaded from DQ pins, and the mask data stored in the mask register is persistently used. This operation is known as persistent write mask, set by LMR and reset by CBRR. 31/40 ¡ Semiconductor Load/Read Color Register: MSM5416273 RAS falling edge --- CAS = TRG = WE = DSF = "H" CAS falling edge --- DSF = "H" The MSM5416273 is provided with an on-chip 16-bit color register for use during the flash write or block write operation. Each bit of the color register corresponds to one of the DRAM I/O blocks. The data presented on the DQi lines is subsequently latched into the color register at the falling edge of either CAS or WE whichever occurs later. The read color register cycle is activated by holding WE "high" at the falling edge of CAS, and throughout the remainder of the cycle. The data in the color register becomes valid on the DQi lines after the specified access times from RAS and TRG are satisfied. During the load/read color register cycle, the memory cells on the row address latched at the falling edge of RAS are refreshed. Load/Read Mask Register: RAS falling edge --- CAS = TRG = WE = DSF = "H" CAS falling edge --- DSF = "L" The MSM5416273 is provided with an on-chip 16-bit mask register for use during the mask write cycle, flash write cycle, block write cycle, masked write transfer, and masked split write transfer. Each bit of the mask register corresponds to one of the DRAM I/O blocks. The data presented on the DQi lines is subsequently latched into the mask register at the falling edge of either CAS or WE whichever occurs later. The read mask register cycle is activated by holding WE "high" at the falling edge of CAS, and throughout the remainder of the cycle. The data in the mask register becomes valid on the DQi lines after the specified access times from RAS and TRG are satisfied. During the load/read mask register cycle, the memory cells on the row address latched at the falling edge of RAS are refreshed. Flash Write: RAS falling edge --- CAS = TRG = DSF = "H", WE = "L" Flash write allows for the data in the color register to be written into all the memory locations of a selected row. Each bit of the color register corresponds to one of the DRAM I/O blocks. The flash write operation can be selectively controlled on an I/O basis in the same manner as the write per bit operation. The mask data is the same as that of a RAM write cycle. 32/40 ¡ Semiconductor MSM5416273 Block Write: RAS falling edge --- CAS = TRG = "H", DSF = "L" CAS falling edge --- DSF = "H" Block write allows for the data in the color register to be written into 8 consecutive column address locations, starting from a selected column address in a selected row. The block write operation can be selectively controlled on an I/O basis, and a column mask capability is also available. This function is implemented as lower byte and upper byte. During a block write cycle, the 3 least significant column address locations (A0C, A1C and A2C) are internally controlled, and only the 6 most significant column addresses (A3C - A8C) are latched at the falling edge of CAS. 1) No mask block write: WE "high" at the falling edge of RAS The data on 16 DQ pins is cleared by the data of the color register. 2) Masked block write: WE "low" at the falling edge of RAS The mask data is the same as that of a RAM write cycle. (new mask and persistent mask) Bit 0 Bit 15 Color Register 11001110 01110011 I/O Mask 11111010 01101011 Column Mask 10010011 00111100 Lower Byte Upper Byte Column 7 1 1 0 0 1 * 1 * * * * * * * * * Column 6 1 1 0 0 1 * 1 * * * * * * * * * Column 5 * * * * * * * * * 1 1 * 0 * 1 1 Column 4 * * * * * * * * * 1 1 * 0 * 1 1 Column 3 1 1 0 0 1 * 1 * * 1 1 * 0 * 1 1 Column 2 * * * * * * * * * 1 1 * 0 * 1 1 Column 1 * * * * * * * * * * * * * * * * Column 0 1 1 0 0 1 * 1 * * * * * * * * * DQ1 DQ2 DQ3 DQ4 DQ5 DQ6 DQ7 DQ8 DQ9 DQ10 DQ11 DQ12 DQ13 DQ14 DQ15 8 Column ¥ 8 DQ (Upper Byte) DQ0 8 Column ¥ 8 DQ (Lower Byte) Note : Location "*" can not be loaded. Example of Block Write 33/40 ¡ Semiconductor MSM5416273 SAM PORT OPERATION Single Register Mode High speed serial read or write operations can be performed through the SAM port independent of the RAM port operation, except during read/write transfer cycles. The preceding transfer operation determines the direction of data flow through the SAM port. If the preceding transfer is a read transfer, the SAM port is in the output mode. If the preceding transfer is write transfer, the SAM port is in the input mode. Serial data can be read out of the SAM after a read transfer has been performed. The data is shifted out of the SAM starting at any of the 512 bits locations. The TAP location corresponds to the column address selected at the falling edge of CAS during the read or write transfer cycle. The SAM registers are configured as a circular data register. The data is shifted out sequentially. It starts from the selected TAP location at the most significant bit (511), then wraps around to the least significant bit (0). Split Register Mode In split register mode data can be shifted into or out of one half of the SAM, while a split read or split write transfer is being performed on the other half of the SAM. Conventional (non split) read, or write transfer cycle must precede any split read or split write transfers. The split read and write transfers will not change the SAM port mode set by the preceding conventional transfer operation. In the split register mode, serial data can be shifted in or out of one of the split SAM registers, starting from any at the 256 TAP locations, excluding the last address of each split SAM the data is shifted in or out sequentially starting from the selected TAP location at the most significant bit (255 or 511) of the first split SAM, and then the SAM pointer moves to the TAP location selected for the second split SAM to shift data in or out sequentially, starts from this TAP location at the most significant bit (511 or 255), and finally wraps around to the least significant bit. TAP 0 1 2 TAP 255 256 257 511 34/40 ¡ Semiconductor MSM5416273 DATA TRANSFER OPERATIONS Upper SAM 256 ¥ 16 256 ¥ 256 ¥ 16 Memory Array Lower SAM 256 ¥ 16 Upper SAM 256 ¥ 16 256 ¥ 256 ¥ 16 Memory Array Serial Decoder 256 ¥ 256 ¥ 16 Memory Array Lower SAM 256 ¥ 16 The MSM5416273 features two types of bidirectional data transfer capability between RAM and SAM. 1) Conventional (non split) transfer: 512 words by 16 bits of data can be loaded from RAM to SAM (Read transfer), or from SAM to RAM (Write transfer). 2) Split transfer: 256 words by 16 bits of data can be loaded from the lower/upper half of the RAM to the lower/upper half of the SAM (Split read transfer), or from the lower/upper half of SAM to the lower/upper half of RAM (Split write transfer). The conventional transfer and split transfer modes are controlled by the DSF input signal. Data transfer is invoked by holding the TRG signal "low" at the falling edge of RAS. The MSM5416273 supports 4 types of transfer operations: Read transfer, Split read transfer, Write transfer and Split write transfer as shown in the truth table. The type of transfer operation is determined by the state of CAS, WE and DSF latched at the falling edge of RAS. During conventional transfer operations, the SAM port is switched from input to output mode (Read transfer), or output to input mode (Write transfer). It remains unchanged during split transfer operation (Split read transfer or Split write transfer). Both RAM and SAM are divided by the most significant row address (AX8), as shown in Figure 1. Therefore, no data transfer between AX8 = 0 side RAM and AX8 = 1 side RAM can be provided through the SAM. Care must be taken if the split read transfer on AX8 = 1 side (or AX8 = 0 side) is provided after the read transfer or the split read transfer, is provided on AX8 = 0 side (or AX8 = 1 side). 256 ¥ 256 ¥ 16 Memory Array AX8 = 0 AX8 = 1 SAM I/O Buffer SDQ0 - 15 Figure 1. RAM and SAM Configuration 35/40 ¡ Semiconductor MSM5416273 Read Transfer: RAS falling edge --- CAS = WE = "H", TRG = DSF = "L" Read transfer consists of loading a selected row of data from the RAM into the SAM register. A read transfer is invoked by holding CAS "high", TRG "low", WE "high", and DSF "low" at the falling edge of RAS. The row address selected at the falling edge of RAS determines the RAM row to be transferred into the SAM. The transfer cycle is completed at the rising edge of TRG. When the transfer is completed, the SAM port is set into the output mode. In a read/real time read transfer cycle, the transfer of a new row of data is completed at the rising edge of TRG, and this data becomes valid on the SDQ lines after the specified access time tSCA from the rising edge of the subsequent SC cycles. The start address of the serial pointer of the SAM is determined by the column address selected at the falling edge of CAS. In a read transfer cycle (which is preceded by a write transfer cycle), SC clock must be held at a constant VIL or VIH after the SC high time has been satisfied. A rising edge of the SC clock must not occur until after the specified delay tTSD from the rising edge of TRG. In a real time read transfer cycle (which is preceded by another read transfer cycle), the previous row data appears on the SQD lines until the TRG signal goes "high", and the serial access time tSCA for the following serial clock is satisfied. This feature allows for the first bit of the new row of data to appear on the serial output as soon as the last bit of the previous row has been strobed without any timing loss. To make this continuous data flow possible, the rising edge of TRG must be synchronized with RAS, CAS, and the subsequent rising edge of SC (tRTH, tCTH and tTSL/tTSD must be satisfied). Masked Write Transfer: RAS falling edge --- CAS = "H", TRG = DSF = "L" WE = "L" Write transfer cycle consists of loading the content of the SAM register into a selected row of the RAM. This write transfer is the same as a mask write operation in RAM, so new and persistent (old) mask modes can be supported. (Masked write transfer) If the SAM data to be transferred must first be loaded through the SAM, a Masked write transfer operation (all DQ pins "low" at falling edge of RAS) must precede the write transfer cycles. A masked write transfer is invoked by holding CAS "high", TRG "low", WE "low", and DSF "low" at the falling edge of RAS. The row address selected at the falling edge of RAS determines the RAM row address into which the data will be transferred. The column address selected at the falling edge of CAS determines the start address of the serial pointer of the SAM. After the write transfer is completed, the SDQ lines are set in the input mode so that serial data synchronized with the SC clock can be loaded. When consecutive write transfer operations are performed, new data must not be written into the serial register until the RAS cycle of the preceding write transfer is completed. Consequently, the SC clock must be held at a constant VIL or VIH during the RAS cycle. A rising edge of the SC clock is only allowed after the specified delay tCSD from the falling edge of the CAS, at which time a new row of data can be written in the serial register. Data transferred to SAM by read transfer cycle or split read transfer cycle can be written to the other address of RAM by write transfer cycle. However, the address to write data must be the same as that of the read transfer cycle (row address AX8). 36/40 ¡ Semiconductor MSM5416273 Split Data Transfer and QSF The MSM5416273 features a bidirectional split data transfer capability between the RAM and SAM. During split data transfer operation, the serial register is split into two halves which can be controlled independently. Split read or split write transfer operation can be performed to or from one half of the serial register, while serial data can be shifted into or out of the other half of the serial register. The most significant column address location (A8C) is controlled internally to determine which half of the serial register will be reloaded from the RAM. QSF is an output which indicates which half of the serial register is in an active state. QSF changes state when the last SC clock is applied to active split SAM. Split Read Transfer: RAS falling edge --- CAS = WE = DSF = "H", TRG = "L" The MSM5416273 supports two types of split register operation. #1 Normal split register operation #2 Boundary split register operation using programmable SAM stops described later. Normal split read transfer consists of loading 256 words by 16 bits of data from a selected row of the split RAM into the corresponding non-active split SAM register. Serial data can be shifted out from the other half of the split SAM register simultaneously. During split read transfer operation, the RAM port input clocks do not have to be synchronized with the serial clock SC, thus eliminating timing restrictions as in the case of real time read transfers. A split read transfer can be performed after a delay of tSTS from the change of state of the QSF output is satisfied. Conventional (non-split) read transfer operation must precede split read transfer cycles. 37/40 ¡ Semiconductor MSM5416273 Masked Split Write Transfer: RAS falling edge --- CAS = DSF = "H", TRG = "L" WE = "L" Split write transfer consists of loading 256 words by 16 bits of data from the non-active split SAM register into a selected row of the corresponding split RAM. Serial data can be shifted into the other half of the split SAM register simultaneously. During split write transfer operation, the RAM port input clocks do not have to be synchronized with the serial clock SC, thus allowing for real time transfer. This operation is the same as a mask write operation in RAM, so new and persistent modes can be supported. A split write transfer can be performed after a delay of tSTS from the change of state of the QSF output is satisfied. A masked write transfer operation must precede split write transfer. The purpose is to switch the SAM port from output mode to input mode, and to set the initial TAP location prior to split write transfer operations. Programmable SAM Stops in Split Transfer Cycle The MSM5416273 has a boundary split register operation using programmable stops. If a CBRS cycle has been performed, the split transfer cycle performs the boundary operation. Figure 2 shows an example of a boundary split register (4 stop points). The stop points define a SAM location at which the access will change from one half of the SAM to the other half (at the TAP address). Lower SAM TAP1 0 Upper SAM TAP3 TAP2 255 256 511 S.T. (TAP3) S.T. (TAP2) Figure 2. Example of Boundary Split Register 38/40 ¡ Semiconductor MSM5416273 SAM Stop Set Cycle (CBRS): RAS falling edge --- CAS = "L", WE = "L", DSF = "H" SAM stop location data (boundaries) are latched from address inputs at the falling edge of RAS. To determine the boundary A4 - A7 are used, and A0 - A3, and A8 are ignored. Once the CBRS is executed, the programmable SAM stop operation continues until CBRR. SAM Stop Boundary Table Number of Stop Points Address Size of Partition A4 A5 A6 A7 1 1 1 1 1 256 2 1 1 1 0 128 4 1 1 0 X 64 8 1 0 X X 32 16 0 X X X 16 Register Reset Cycle (CBRR): RAS falling edge --- CAS = "L", WE = "H", DSF = "L" A CBRR can reset the programmable SAM stop operation, and persistent mask write operation. The CBRR will take effect immediately; it doesn’t require a split transfer cycle. POWER UP Power must be applied to the RAS and TRG input signals to pull them "high" before, or at the same time as, the VCC supply is turned on. After power-up, a pause of 200 ms minimum is required with RAS and TRG held "high". After the pause, a minimum of 8 RAS and 8 SC dummy cycles must be performed to stabilize the internal circuitry, before valid read, write or transfer operations can begin. During the initialization period, the TRG signal must be held "high". If the internal refresh counter is used, a minimum 8 CAS before RAS cycles are required instead of 8 RAS cycles. (NOTE) INITIAL STATE AFTER POWER UP The initial state can not be guaranteed for various power up conditions and input signal levels. Therefore, it is recommended that the initial state be set (ex. Perform a CBRR cycle to select Non Persistent Write-per-bit mode) after the initialization of the device is performed and before valid operations begin. 39/40 ¡ Semiconductor MSM5416273 PACKAGE DIMENSIONS (Unit : mm) SSOP64-P-525-0.80-K Mirror finish Package material Lead frame material Pin treatment Solder plate thickness Package weight (g) Epoxy resin 42 alloy Solder plating 5 mm or more 1.34 TYP. Notes for Mounting the Surface Mount Type Package The SOP, QFP, TSOP, SOJ, QFJ (PLCC), SHP and BGA are surface mount type packages, which are very susceptible to heat in reflow mounting and humidity absorbed in storage. Therefore, before you perform reflow mounting, contact Oki’s responsible sales person for the product name, package name, pin number, package code and desired mounting conditions (reflow method, temperature and times). 40/40