EDS1616GGBH-1A-E

PRELIMINARY DATA SHEET 16M bits SDRAM EDS1616GGBH (1M words × 16 bits) Specifications • Density: 16M bits • Organization ⎯ 512K words × 16 bits × 2 banks • Package: 60-ball FBGA ⎯ Lead-free (RoHS compliant) • Power supply: VDD, VDDQ = 3.3V ± 0.3V • Clock frequency: 100MHz (max.) • Two internal banks for concurrent operation • Interface: LVTTL • Burst lengths (BL): 1, 2, 4, 8, full page • Burst type (BT): ⎯ Sequential (1, 2, 4, 8, full page) ⎯ Interleave (1, 2, 4, 8) • /CAS Latency (CL): 2, 3 • Precharge: auto precharge operation for each burst access • Refresh: auto-refresh, self-refresh • Refresh cycles: 2048 cycles/32ms ⎯ Average refresh period: 15.6μs • Operating ambient temperature range ⎯ TA = 0°C to +70°C Pin Configurations /xxx indicates active low signal. 60-ball FBGA 1 A VSS B DQ14 C DQ13 VDDQ D DQ12 E DQ10 F DQ9 G DQ8 H J NC NC DQ7 VDDQ VSSQ DQ6 VSSQ VDDQ DQ5 DQ11 DQ4 DQ3 VSSQ DQ2 VSSQ VDDQ DQ1 DQ15 DQ0 VDD 2 3 4 5 6 7 EO Features • Single pulsed /RAS • Burst read/write operation and burst read/single write operation capability • Byte control by UDQM and LDQM • tDPL = 1CLK Document No. E0682E20 (Ver. 2.0) Date Published December 2005 (K) Japan Printed in Japan URL: http://www.elpida.com L Pr K L M N P R A0 to A10 BA DQ0 to DQ15 /CS /RAS /CAS /WE LDQM, UDQM NC NC NC NC NC UDQM LDQM /WE NC CLK /RAS /CAS CKE NC NC /CS This product became EOL in March, 2007. ©Elpida Memory, Inc. 2005 od BA A9 A8 A7 A6 A5 VSS A4 NC NC A0 A10 A2 A1 A3 VDD Address input Bank select address Data-input/output Chip select Row address strobe Column address strobe Write enable Input/output mask t uc (Top view) CKE CLK VDD VSS VDDQ VSSQ NC Clock enable Clock input Power for internal circuit Ground for internal circuit Power for DQ circuit Ground for DQ circuit No connection EDS1616GGBH Ordering Information Part number EDS1616GGBH-1A-E Supply voltage 3.3V Organization (words × bits) Internal Banks 1M × 16 2 Clock frequency MHz (max.) 100 /CAS latency 2 Package 60-ball FBGA Part Number Elpida Memory Type D: Monolithic Device Environment Code E: Lead Free EO Product Family S: SDRAM Density / Bank 16: 16M/2-bank Organization 16: x16 Die Rev. Speed 1A: 100MHz/CL2 Power Supply, Interface G: 3.3V, LVTTL, tDPL = 1CLK Package BH: FBGA Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr od t uc 2 EDS1616GGBH CONTENTS Specifications ................................................................................................................................................ 1 Features ........................................................................................................................................................ 1 Pin Configurations......................................................................................................................................... 1 Ordering Information ..................................................................................................................................... 2 Part Number.................................................................................................................................................. 2 Electrical Specifications ................................................................................................................................ 4 Block Diagram............................................................................................................................................. 10 Pin Function ................................................................................................................................................ 11 Command Operation................................................................................................................................... 12 Simplified State Diagram ............................................................................................................................ 20 Mode Register Configuration ...................................................................................................................... 21 Power-up sequence .................................................................................................................................... 23 Operation of the SDRAM ............................................................................................................................ 24 Timing Waveforms ...................................................................................................................................... 40 Package Drawing........................................................................................................................................ 46 Recommended Soldering Conditions ......................................................................................................... 47 EO Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr od t uc 3 EDS1616GGBH Electrical Specifications • All voltages are referenced to VSS (GND). • After power up, execute power up sequence and initialization sequence before proper device operation is achieved (refer to the Power up sequence). Absolute Maximum Ratings Parameter Voltage on any pin relative to VSS Supply voltage relative to VSS Short circuit output current Power dissipation Operating ambient temperature Symbol VT VDD IOS PD TA Tstg Rating –0.5 to VDD + 0.5 (≤ 4.6 (max.)) –0.5 to +4.6 50 1.0 0 to +70 –55 to +125 Unit V V mA W °C °C Note EO Storage temperature Parameter Supply voltage Input high voltage Input low voltage Caution Exposing the device to stress above those listed in Absolute Maximum Ratings could cause permanent damage. The device is not meant to be operated under conditions outside the limits described in the operational section of this specification. Exposure to Absolute Maximum Rating conditions for extended periods may affect device reliability. Recommended DC Operating Conditions (TA = 0°C to +70°C) Symbol VDD, VDDQ VSS, VSSQ min. 3.0 0 2.0 –0.3 max. 3.6 0 VDD + 0.3 0.8 Unit V V V V Notes 1 2 3 4 L VIH VIL Notes: 1. 2. 3. 4. The supply voltage with all VDD and VDDQ pins must be on the same level. The supply voltage with all VSS and VSSQ pins must be on the same level. VIH (max.) = VDD + 1.5V (pulse width ≤ 5ns). VIL (min.) = VSS – 1.5V (pulse width ≤ 5ns). Preliminary Data Sheet E0682E20 (Ver. 2.0) Pr 4 od t uc EDS1616GGBH DC Characteristics 1 (TA = 0°C to +70°C, VDD, VDDQ = 3.3V ± 0.3V, VSS, VSSQ = 0V) Parameter Operating current Standby current in power down Standby current in power down (input signal stable) Standby current in non power down Standby current in non power down (input signal stable) Active standby current in power down Symbol IDD1 IDD2P IDD2PS IDD2N IDD2NS IDD3P IDD3PS IDD3N IDD3NS IDD4 IDD5 IDD6 Grade max. 80 1 1 15 5 3 3 25 15 100 80 1 Unit mA mA mA mA mA mA mA mA mA mA mA mA Test condition Burst length = 1 tRC = tRC (min.) CKE = VIL, tCK = tCK (min.) CKE = VIL, tCK = ∞ CKE, /CS = VIH, tCK = tCK (min.) CKE = VIH, tCK = ∞, /CS = VIH CKE = VIL, tCK = tCK (min.) CKE = VIL, tCK = ∞ CKE, /CS = VIH, tCK = tCK (min.) CKE = VIH, tCK = ∞, /CS = VIH tCK = tCK (min.), BL = 4 tRC = tRC (min.) VIH ≥ VDD – 0.2V VIL ≤ 0.2V Notes 1, 2, 3 6 7 4 8 1, 2, 6 2, 7 1, 2, 4 2, 8 1, 2, 5 3 EO Burst operating current Refresh current Self refresh current Active standby current in power down (input signal stable) Active standby current in non power down Active standby current in non power down (input signal stable) Notes: 1. IDD depends on output load condition when the device is selected. IDD (max.) is specified at the output open condition. 2. One bank operation. 3. Input signals are changed once per one clock. 4. Input signals are changed once per two clocks. 5. Input signals are changed once per four clocks. 6. After power down mode, CLK operating current. 7. After power down mode, no CLK operating current. 8. Input signals are VIH or VIL fixed. Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr 5 od t uc EDS1616GGBH DC Characteristics 2 (TA = 0°C to +70°C, VDD, VDDQ = 3.3V ± 0.3V, VSS, VSSQ = 0V) Parameter Input leakage current Output leakage current Output high voltage Output low voltage Symbol ILI ILO VOH VOL min. –1 –1.5 2.4 — max. 1 1.5 — 0.4 Unit µA µA V V Test condition 0 ≤ VIN ≤ VDD 0 ≤ VOUT ≤ VDD, DQ = disable IOH = –2 mA IOL = 2 mA Notes Pin Capacitance (TA = 25°C, VDD, VDDQ = 3.3V ± 0.3V) Parameter Input capacitance Symbol CI1 CI2 CI/O Pins CLK min. TBD typ. TBD TBD TBD max. TBD TBD TBD Unit pF pF pF Notes 1, 2, 4 1, 2, 4 1, 2, 3, 4 Address, CKE, /CS, TBD /RAS, /CAS, /WE, DQM DQ TBD EO Notes: 1. 2. 3. 4. Data input/output capacitance Capacitance measured with Boonton Meter or effective capacitance measuring method. Measurement condition: f = 1MHz, 1.4V bias, 200mV swing. DQM = VIH to disable DOUT. This parameter is sampled and not 100% tested. Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr od t uc 6 EDS1616GGBH AC Characteristics (TA = 0°C to +70°C, VDD, VDDQ = 3.3V ± 0.3V, VSS, VSSQ = 0V) -1A Parameter System clock cycle time (CL = 2) CLK high pulse width CLK low pulse width Access time from CLK Data-out hold time CLK to Data-out low impedance CLK to Data-out high impedance Symbol tCK tCH tCL tAC tOH tLZ tHZ tSI tHI tRC tRAS tRCD tRP tDPL tDAL tRRD tT tREF min. 10 3.5 3.5 — 2.5 0 — 2.5 1 70 50 20 20 10 1CLK + 20ns 20 0.5 — max. — — — 8 — — 8 — — — 120000 — — — — — 5 32 ns ns ms 1 Unit ns ns ns ns ns ns ns ns ns ns ns ns ns ns Notes 1 1 1 1, 2 1, 2 1, 2, 3 1, 4 1 1 1 1 1 1 1 EO Input setup time Input hold time Last data into active latency Transition time (rise and fall) Refresh period (2048 refresh cycles) Ref/Active to Ref/Active command period Active to Precharge command period Active command to column command (same bank) Precharge to active command period Write recovery or data-in to precharge lead time Active (a) to Active (b) command period L Notes: 1. 2. 3. 4. AC measurement assumes tT = 0.5ns. Reference level for timing of input signals is 1.4V. Access time is measured at 1.4V. Load condition is CL = 30pF. tLZ (min.) defines the time at which the outputs achieves the low impedance state. tHZ (max.) defines the time at which the outputs achieves the high impedance state. Preliminary Data Sheet E0682E20 (Ver. 2.0) Pr 7 od t uc EDS1616GGBH Test Conditions • AC high level voltage/low level input voltage: 2.4V/0.4V • Input and output timing reference levels: 1.4V • Input waveform and output load: See following figures 2.4 V input 0.4 V 2.0 V 0.8 V I/O CL tT tT Input waveform and Output load EO Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr od t uc 8 EDS1616GGBH Relationship Between Frequency and Minimum Latency Parameter Frequency (MHz) tCK (ns) Active command to column command (same bank) Active command to active command (same bank) Active command to precharge command (same bank) Precharge command to active command (same bank) Write recovery or data-in to precharge command (same bank) Active command to active command (different bank) Self refresh exit time Last data in to active command (Auto precharge, same bank) Self refresh exit to command input Precharge command to high impedance (CL = 2) (CL = 3) Last data out to active command (Auto precharge, same bank) Last data out to precharge (early precharge) (CL = 2) (CL = 3) Column command to column command Write command to data in latency DQM to data in DQM to data out CKE to CLK disable Register set to active command /CS to command disable Power down exit to command input Symbol lRCD lRC lRAS lRP lDPL lRRD lSREX lDAL lSEC lHZP lHZP lAPR lEP lEP lCCD -1A 100 10 2 7 5 2 1 2 1 3 6 2 3 1 –1 –2 1 Unit tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK tCK Notes 1 1 1 1 1 1 2 = [lDPL + lRP] = [lRC] 3 EO Notes: 1. lRCD to lRRD are recommended value. 2. Be valid [DESL] or [NOP] at next command of self refresh exit. 3. Except [DESL] and [NOP] Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr lWCD lDID 0 0 lDOD lCLE 2 1 lMRD lCDD lPEC 2 0 1 od tCK t uc 9 EDS1616GGBH Block Diagram CLK CKE Clock Generator Bank 1 Address Mode Register Row Decoder Row Address Buffer & Refresh Counter Bank 0 EO Command Decoder /CS /RAS /CAS /WE Sense Amplifier Control Logic Data Control Circuit Input & Output Buffer Latch Circuit Column Address Buffer & Burst Counter Column Decoder & Latch Circuit DQM DQ Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr od t uc 10 EDS1616GGBH Pin Function CLK (input pin) CLK is the master clock input. Other inputs signals are referenced to the CLK rising edge. CKE (input pins) CKE determine validity of the next CLK (clock). If CKE is high, the next CLK rising edge is valid; otherwise it is invalid. If the CLK rising edge is invalid, the internal clock is not issued and the Synchronous DRAM suspends operation. When the Synchronous DRAM is not in burst mode and CKE is negated, the device enters power down mode. During power down mode, CKE must remain low. /CS (input pins) /CS low starts the command input cycle. When /CS is high, commands are ignored but operations continue. /RAS, /CAS, and /WE (input pins) /RAS, /CAS and /WE have the same symbols on conventional DRAM but different functions. For details, refer to the command table. A0 to A10 (input pins) Row Address is determined by A0 to A10 at the CLK (clock) rising edge in the active command cycle. Column Address is determined by A0 to A7 at the CLK rising edge in the read or write command cycle. A10 defines the precharge mode. When A10 is high in the precharge command cycle, all banks are precharged; when A10 is low, only the bank selected by BA is precharged. When A10 is high in read or write command cycle, the precharge starts automatically after the burst access. BA (input pin) BA is bank select signal (BS). (See Bank Select Signal Table) [Bank Select Signal Table] Bank 0 Bank 1 BA L EO Remark: H: VIH. L: VIL. UDQM and LDQM (input pins) UDQM and LDQM control input/output buffers. UDQM and LDQM control upper byte (DQ8 to DQ15) and lower byte (DQ0 to DQ7). DQ0 to DQ15 (input/output pins) DQ pins have the same function as I/O pins on a conventional DRAM. VDD, VSS, VDDQ, VSSQ (Power supply) VDD and VSS are power supply pins for internal circuits. VDDQ and VSSQ are power supply pins for the output buffers. Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr H od 11 t uc EDS1616GGBH Command Operation Command Truth Table The SDRAM recognizes the following commands specified by the /CS, /RAS, /CAS, /WE and address pins. CKE Function Device deselect No operation Burst stop Read Read with auto precharge Write Symbol DESL NOP BST READ READA WRIT WRITA ACT PRE PALL MRS n–1 H H H H H H H H H H H n × × × × × × × × × × × /CS H L L L L L L L L L L /RAS × H H H H H H L L L L /CAS × H H L L L L H H H L /WE × H L H H L L H L L L BA × × × V V V V V V × L A10 × × × L H L H V L H L A0 to A9 × × × V V V V V × × V EO Write with auto precharge Bank activate Precharge select bank Precharge all banks Mode register set Remark: H: VIH. L: VIL. ×: VIH or VIL. V: Valid address input. Device deselect command [DESL] When this command is set (/CS is High), the SDRAM ignore command input at the clock. However, the internal status is held. No operation [NOP] This command is not an execution command. However, the internal operations continue. Burst stop command [BST] This command can stop the current burst operation. Column address strobe and read command [READ] This command starts a read operation. In addition, the start address of burst read is determined by the column address (see Address Pins Table in Pin Function) and the bank select address (BA). After the read operation, the output buffer becomes High-Z. Read with auto-precharge [READA] This command automatically performs a precharge operation after a burst read with a burst length of 1, 2, 4 or 8. Column address strobe and write command [WRIT] This command starts a write operation. When the burst write mode is selected, the column address (see Address Pins Table in Pin Function) and the bank select address (BA) become the burst write start address. When the single write mode is selected, data is only written to the location specified by the column address (see Address Pins Table in Pin Function) and the bank select address (BA). Write with auto-precharge [WRITA] This command automatically performs a precharge operation after a burst write with a length of 1, 2, 4 or 8, or after a single write operation. Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr 12 od t uc EDS1616GGBH Row address strobe and bank activate [ACT] This command activates the bank that is selected by BA and determines the row address (A0 to A10). (See Bank Select Signal Table) Precharge selected bank [PRE] This command starts precharge operation for the bank selected by BA. (See Bank Select Signal Table) [Bank Select Signal Table] BA Bank 0 Bank 1 L H Remark: H: VIH. L: VIL. Precharge all banks [PALL] This command starts a precharge operation for all banks. Refresh [REF/SELF] This command starts the refresh operation. There are two types of refresh operation, the one is auto-refresh, and the other is self-refresh. For details, refer to the CKE truth table section. Mode register set [MRS] The SDRAM has a mode register that defines how it operates. The mode register is specified by the address pins (A0 to A10 and BA) at the mode register set cycle. For details, refer to the Mode Register Configuration. After power on, the contents of the mode register are undefined, execute the mode register set command to set up the mode register. EO Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr od t uc 13 EDS1616GGBH DQM Truth Table CKE Commands Upper byte write enable/output enable Lower byte write enable/output enable Upper byte write inhibit/output disable Lower byte write inhibit/output disable Symbol ENBU ENBL MASKU MASKL n–1 H H H H n × × × × UDQM L × H × LDQM × L × H Remark: H: VIH. L: VIL. ×: VIH or VIL Write: lDID is needed. Read: lDOD is needed. EO CKE Truth Table Current state Activating Any Idle Function Clock suspend Idle Self refresh Idle Power down CKE Symbol n–1 H L L REF SELF H H L L H H L L n L L H H L H H L L H H /CS × × × L L L H L H H L /RAS × × × L L H × H × × H /CAS × × × L L H × H × × H /WE × × × H H H × H × × H Address × × × × × × × × × × × Clock suspend mode entry Clock suspend mode Clock suspend mode exit CBR (auto) refresh command Self refresh entry Remark: H: VIH. L: VIL. ×: VIH or VIL Preliminary Data Sheet E0682E20 (Ver. 2.0) L Self refresh exit Power down entry Power down exit Pr 14 od t uc EDS1616GGBH Function Truth Table The following table shows the operations that are performed when each command is issued in each mode of the SDRAM. The following table assumes that CKE is high. Current state Precharge /CS H L L L L L L L L /RAS × H H H H L L L L × H H H H L /CAS × H H L L H H L L × H H L L H /WE × H L H L H L H L × H L H L H L H L × Address × × × BA, CA, A10 BA, CA, A10 BA, RA BA, A10 × MODE × × × BA, CA, A10 BA, CA, A10 BA, RA BA, A10 × MODE × × × Command DESL NOP BST READ/READA WRIT/WRITA ACT PRE, PALL REF, SELF MRS DESL NOP BST READ/READA WRIT/WRITA ACT PRE, PALL REF, SELF MRS DESL NOP BST READ/READA WRIT/WRITA ACT Operation Enter IDLE after tRP Enter IDLE after tRP ILLEGAL ILLEGAL*3 ILLEGAL*3 ILLEGAL*3 NOP*5 ILLEGAL ILLEGAL NOP NOP ILLEGAL ILLEGAL*4 ILLEGAL*4 Bank and row active NOP Refresh Mode register set*8 NOP NOP ILLEGAL Begin read*6 Begin write*6 Other bank active ILLEGAL on same bank*2 Precharge*7 EO Idle H L L L L L L L L Row active H L L L L L L L L Preliminary Data Sheet E0682E20 (Ver. 2.0) L L H L × H H H H L L L L L × L L H H L L H H L L Pr H L H L BA, CA, A10 BA, CA, A10 BA, RA H L H L BA, A10 × MODE od PRE, PALL REF, SELF MRS ILLEGAL ILLEGAL t uc 15 EDS1616GGBH Current state Read /CS H L L L L L L L L /RAS × H H H H L L L L × H H H H L L /CAS × H H L L H H L L × H H L L H H /WE × H L H L H L H L × H L H L H L H L × H L Address × × × BA, CA, A10 BA, CA, A10 BA, RA BA, A10 × MODE × × × BA, CA, A10 BA, CA, A10 BA, RA BA, A10 × MODE × × × Command DESL NOP BST READ/READA WRIT/WRITA ACT PRE, PALL REF, SELF MRS DESL NOP BST READ/READA WRIT/WRITA ACT PRE, PALL REF, SELF MRS DESL NOP BST READ/READA WRIT/WRITA ACT Operation Continue burst to end Continue burst to end Burst stop Continue burst read to /CAS latency and New read Term burst read/start write Other bank active ILLEGAL on same bank*2 Term burst read and Precharge ILLEGAL ILLEGAL Continue burst to end and precharge Continue burst to end and precharge ILLEGAL ILLEGAL*3 ILLEGAL*3 Other bank active ILLEGAL on same bank*2 ILLEGAL*3 ILLEGAL ILLEGAL Continue burst to end Continue burst to end Burst stop Term burst and New read Term burst and New write Other bank active ILLEGAL on same bank*3 Term burst write and Precharge*1 ILLEGAL ILLEGAL EO Read with autoprecharge H L L L L L L L L Write H L L L L L L L L Preliminary Data Sheet E0682E20 (Ver. 2.0) L L × H H H H L L L L L × H L L H L L H H L L Pr H L BA, CA, A10 BA, CA, A10 BA, RA H L BA, A10 H L × MODE PRE, PALL od REF, SELF MRS t uc 16 EDS1616GGBH Current state Write with autoprecharge /CS H L L L L L L L /RAS × H H H H L L L L × H H H H L L /CAS × H H L L H H L L × H H L L H H /WE × H L H L H L H L × H L H L H L H L × H L Address × × × BA, CA, A10 BA, CA, A10 BA, RA BA, A10 × MODE × × × BA, CA, A10 BA, CA, A10 BA, RA BA, A10 × MODE × × × Command DESL NOP BST READ/READA WRIT/WRITA ACT PRE, PALL REF, SELF MRS DESL NOP BST READ/READA WRIT/WRITA ACT PRE, PALL REF, SELF MRS DESL NOP BST Operation Continue burst to end and precharge Continue burst to end and precharge ILLEGAL ILLEGAL*3 ILLEGAL*3 Other bank active ILLEGAL on same bank*3 ILLEGAL*3 ILLEGAL ILLEGAL Enter IDLE after tRC Enter IDLE after tRC ILLEGAL ILLEGAL*4 ILLEGAL*4 ILLEGAL*4 ILLEGAL*4 ILLEGAL ILLEGAL NOP NOP ILLEGAL ILLEGAL*4 ILLEGAL*4 Bank and row active*9 NOP Refresh*9 Mode register set*8 EO L Refresh (auto-refresh) H L L L L L L L L Mode register set H L L L L L L L L Remark: H: VIH. L: VIL. ×: VIH or VIL Notes: 1. An interval of tDPL is required between the final valid data input and the precharge command. 2. If tRRD is not satisfied, this operation is illegal. 3. Illegal for same bank, except for another bank. 4. Illegal for all banks. 5. NOP for same bank, except for another bank. 6. Illegal if tRCD is not satisfied. 7. Illegal if tRAS is not satisfied. 8. MRS command must be issued after DOUT finished, in case of DOUT remaining. 9. Illegal if lMRD is not satisfied. Preliminary Data Sheet E0682E20 (Ver. 2.0) L L × L × L L H H H H L L L L H H L L H H L L Pr H L BA, CA, A10 BA, CA, A10 BA, RA H L BA, A10 H L × MODE READ/READA WRIT/WRITA ACT PRE, PALL REF, SELF MRS od 17 t uc EDS1616GGBH Command Truth Table for CKE CKE Current State Self refresh n–1 n H L L L L L Self refresh recovery H H H × H H H H L H H H H L L L L × H H L /CS × H L L L × H L L L H L L L × H L × /RAS /CAS /WE Address × × H H L × × H H L × H H L × × × × H × × H L × × × H L × × H L × × × H × × × H L L × × × × × × × × × × × × × × × × H × × × × H L × × × × × × × × × × × × × × × × × × Operation INVALID, CLK (n – 1) would exit self refresh Self refresh recovery Self refresh recovery ILLEGAL ILLEGAL Continue self refresh Idle after tRC Idle after tRC ILLEGAL ILLEGAL ILLEGAL ILLEGAL ILLEGAL ILLEGAL INVALID, CLK (n – 1) would exit power down EXIT power down EXIT power down Continue power down mode Refer to operations in Function Truth Table Refer to operations in Function Truth Table Refer to operations in Function Truth Table CBR (auto) Refresh Notes EO H H H H H L L L Power down H All banks idle H H H H H H H H H H L L Row active Any state other than listed above H L H H L L Remark: H: VIH. L: VIL. ×: VIH or VIL Notes: 1. Self refresh can be entered only from the all banks idle state. Power down can be entered only from all banks idle. Clock suspend can be entered only from following states, row active, read, read with autoprecharge, write and write with auto precharge. 2. Must be legal command as defined in Function Truth Table. Preliminary Data Sheet E0682E20 (Ver. 2.0) L H H L L L H H H H L L L L L H L × × H L H L H L L L L L H L × H L L L × × × × × × × × L L × × × × × × × × Pr × × × × × H L L × × × × × × × × H L × × × × × × × × × × × × × × × × OPCODE Refer to operations in Function Truth Table Begin power down next cycle Refer to operations in Function Truth Table Refer to operations in Function Truth Table Self refresh 1 od Exit power down next cycle Power down Clock suspend Maintain clock suspend OPCODE Refer to operations in Function Truth Table 1 1 2 Refer to operations in Function Truth Table Refer to operations in Function Truth Table Begin clock suspend next cycle Exit clock suspend next cycle t uc 18 EDS1616GGBH Clock suspend mode entry The SDRAM enters clock suspend mode from active mode by setting CKE to Low. If command is input in the clock suspend mode entry cycle, the command is valid. The clock suspend mode changes depending on the current status (1 clock before) as shown below. ACTIVE clock suspend This suspend mode ignores inputs after the next clock by internally maintaining the bank active status. READ suspend and READ with Auto-precharge suspend The data being output is held (and continues to be output). WRITE suspend and WRIT with Auto-precharge suspend In this mode, external signals are not accepted. However, the internal state is held. EO Clock suspend During clock suspend mode, keep the CKE to Low. Clock suspend mode exit The SDRAM exits from clock suspend mode by setting CKE to High during the clock suspend state. IDLE In this state, all banks are not selected, and completed precharge operation. Auto-refresh command [REF] When this command is input from the IDLE state, the SDRAM starts auto-refresh operation. (The auto-refresh is the same as the CBR refresh of conventional DRAMs.) During the auto-refresh operation, refresh address and bank select address are generated inside the SDRAM. For every auto-refresh cycle, the internal address counter is updated. Accordingly, 2048 times are required to refresh the entire memory. Before executing the auto-refresh command, all the banks must be in the IDLE state. In addition, since the precharge for all banks is automatically performed after auto-refresh, no precharge command is required after auto-refresh. Self-refresh entry [SELF] When this command is input during the IDLE state, the SDRAM starts self-refresh operation. After the execution of this command, self-refresh continues while CKE is Low. Since self-refresh is performed internally and automatically, external refresh operations are unnecessary. Power down mode entry When this command is executed during the IDLE state, the SDRAM enters power down mode. In power down mode, power consumption is suppressed by cutting off the initial input circuit. Self-refresh exit When this command is executed during self-refresh mode, the SDRAM can exit from self-refresh mode. After exiting from self-refresh mode, the SDRAM enters the IDLE state. Power down exit When this command is executed at the power down mode, the SDRAM can exit from power down mode. After exiting from power down mode, the SDRAM enters the IDLE state. Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr 19 od t uc EDS1616GGBH Simplified State Diagram SELF REFRESH SR ENTRY SR EXIT MODE REGISTER SET MRS IDLE REFRESH *1 AUTO REFRESH CKE CKE_ EO WRITE SUSPEND WRITEA SUSPEND POWER APPLIED ACTIVE CLOCK SUSPEND ACTIVE IDLE POWER DOWN CKE_ CKE ROW ACTIVE BST BST WRITE Write WRITE WITH AP READ READ WITH AP READ WITH AP WRITE READ Read CKE_ READ CKE READ WITH AP CKE_ READA CKE READA SUSPEND READ SUSPEND Note: 1. After the auto-refresh operation, precharge operation is performed automatically and enter the IDLE state. Preliminary Data Sheet E0682E20 (Ver. 2.0) L CKE_ CKE CKE_ CKE WRITE WRITE WITH AP WRITE WITH AP PRECHARGE Automatic transition after completion of command. Transition resulting from command input. Pr WRITEA PRECHARGE PRECHARGE POWER ON PRECHARGE PRECHARGE od 20 t uc EDS1616GGBH Mode Register Configuration Mode Register Set The mode register is set by the input to the address pins (A0 to A10 and BA) during mode register set cycles. The mode register consists of five sections, each of which is assigned to address pins. BA, A8, A9, A10: (OPCODE): The SDRAM has two types of write modes. One is the burst write mode, and the other is the single write mode. These bits specify write mode. • Burst read and burst write: Burst write is performed for the specified burst length starting from the column address specified in the write cycle. • Burst read and single write: Data is only written to the column address specified during the write cycle, regardless of the burst length. A7: Keep this bit Low at the mode register set cycle. If this pin is high, the vender test mode is set. A6, A5, A4: (LMODE): These pins specify the /CAS latency. A3: (BT): A burst type is specified. A2, A1, A0: (BL): These pins specify the burst length. BA A10 A9 A8 A7 0 A6 A5 LMODE A4 A3 BT A2 A1 BL A0 EO BA 0 0 A10 0 X OPCODE Preliminary Data Sheet E0682E20 (Ver. 2.0) L A6 0 0 0 0 1 A5 0 0 1 1 X 0 1 0 1 X A9 0 1 0 A4 CAS latency R R 2 3 A3 Burst type 0 Sequential 1 Interleave A2 A1 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1 A0 0 1 0 1 0 1 0 1 Burst length BT=0 1 2 4 8 R R R F.P. BT=1 1 2 4 8 R R R R A8 Write mode 0 Burst read and burst write Pr R Burst read and single write Mode Register Set od 21 F.P.: Full Page R is Reserved (inhibit) X: 0 or 1 t uc EDS1616GGBH Burst Sequence Burst length = 2 Starting Ad. Addressing(decimal) A0 0 1 Sequential Interleave 0, 1, 1, 0, 0, 1, 1, 0, Burst length = 4 Starting Ad. Addressing(decimal) A1 0 0 1 1 A0 0 1 0 1 Sequential 0, 1, 2, 3, 1, 2, 3, 0, 2, 3, 0, 1, 3, 0, 1, 2, Interleave 0, 1, 2, 3, 1, 0, 3, 2, 2, 3, 0, 1, 3, 2, 1, 0, Burst length = 8 Starting Ad. A2 0 0 0 0 A1 0 0 1 1 Addressing(decimal) Interleave 0, 1, 2, 3, 4, 5, 6, 7, 1, 0, 3, 2, 5, 4, 7, 6, 2, 3, 0, 1, 6, 7, 4, 5, 3, 2, 1, 0, 7, 6, 5, 4, 4, 5, 6, 7, 0, 1, 2, 3, 5, 4, 7, 6, 1, 0, 3, 2, 6, 7, 4, 5, 2, 3, 0, 1, 7, 6, 5, 4, 3, 2, 1, 0, 0 1 0 1 0 1 0 1 0, 1, 2, 3, 4, 5, 6, 7, 1, 2, 3, 4, 5, 6, 7, 0, 2, 3, 4, 5, 6, 7, 0, 1, 3, 4, 5, 6, 7, 0, 1, 2, 4, 5, 6, 7, 0, 1, 2, 3, 5, 6, 7, 0, 1, 2, 3, 4, 6, 7, 0, 1, 2, 3, 4, 5, 7, 0, 1, 2, 3, 4, 5, 6, A0 Sequential EO 1 1 0 1 1 0 1 1 Full page burst is available only for sequential addressing. The addressing sequence is started from the column address that is asserted by read/write command. And the address is increased one by one. It is back to the address 0 when the address reaches at the end of address 255. “Full page burst” stops the burst read/write with burst stop command. Preliminary Data Sheet E0682E20 (Ver. 2.0) L Burst Sequence Pr 22 od t uc EDS1616GGBH Power-up sequence Power-up sequence The SDRAM should be goes on the following sequence with power up. The CLK, CKE, /CS, DQM and DQ pins keep low till power stabilizes. The CLK pin is stabilized within 100 µs after power stabilizes before the following initialization sequence. The CKE and DQM is driven to high between power stabilizes and the initialization sequence. This SDRAM has VDD clamp diodes for CLK, CKE, address, /RAS, /CAS, /WE, /CS, DQM and DQ pins. If these pins go high before power up, the large current flows from these pins to VDD through the diodes. EO Initialization sequence VDD, VDDQ CKE, DQM CLK /CS, DQ When 200 µs or more has past after the above power-up sequence, all banks must be precharged using the precharge command (PALL). After tRP delay, set 8 or more auto refresh commands (REF). Set the mode register set command (MRS) to initialize the mode register. We recommend that by keeping DQM and CKE to High, the output buffer becomes High-Z during Initialization sequence, to avoid DQ bus contention on memory system formed with a number of device. Power up sequence 100 μs Initialization sequence 200 μs Preliminary Data Sheet E0682E20 (Ver. 2.0) L 0V Low Low Low Power stabilize Pr 23 Power-up sequence and Initialization sequence od t uc EDS1616GGBH Operation of the SDRAM Read/Write Operations Bank active Before executing a read or write operation, the corresponding bank and the row address must be activated by the bank active (ACT) command. An interval of tRCD is required between the bank active command input and the following read/write command input. Read operation A read operation starts when a read command is input. Output buffer becomes Low-Z in the (/CAS Latency - 1) cycle after read command set. The SDRAM can perform a burst read operation. The burst length can be set to 1, 2, 4, 8 and full page (full page: sequential only). The start address for a burst read is specified by the column address and the bank select address at the read command set cycle. In a read operation, data output starts after the number of clocks specified by the /CAS Latency. The /CAS Latency can be set to 2 or 3. When the burst length is 1, 2, 4, 8 and full page (full page: sequential only), the DOUT buffer automatically becomes High-Z at the next clock after the successive burst-length data has been output. The /CAS latency and burst length must be specified at the mode register. CLK EO Command Address DQ CL = 2 CL = 3 CLK Command Address ACT Row tRCD READ ACT BL = 1 DQ BL = 2 BL = 4 out 0 out 1 out 2 BL = 8 Preliminary Data Sheet E0682E20 (Ver. 2.0) L Row Column out 0 out 1 out 0 out 2 out 1 out 3 out 2 out 3 CL = /CAS latency Burst Length = 4 Pr /CAS Latency tRCD READ od t uc BL : Burst Length /CAS Latency = 2 Column out 0 out 0 out 1 out 0 out 1 out 2 out 3 out 3 out 4 out 5 out 6 out 7 Burst Length 24 EDS1616GGBH Write operation Burst write or single write mode is selected by the OPCODE of the mode register. 1. Burst write: A burst write operation is enabled by setting OPCODE (A9, A8) to (0, 0). A burst write starts in the same clock as a write command set. (The latency of data input is 0 clock.) The burst length can be set to 1, 2, 4 , 8 and full page (full page: sequential only),, like burst read operations. The write start address is specified by the column address and the bank select address at the write command set cycle. CLK tRCD Command Address ACT WRIT Row Column BL = 1 BL = 2 BL = 4 BL = 8 in 0 in 0 in 0 in 0 in 1 in 1 in 1 in 2 in 2 EO DQ in 3 in 3 in 4 in 5 in 6 in 7 CL = 2, 3 Burst write 2. Single write: A single write operation is enabled by setting OPCODE (A9, A8) to (1, 0). In a single write operation, data is only written to the column address and the bank select address specified by the write command set cycle without regard to the burst length setting. (The latency of data input is 0 clock). Preliminary Data Sheet E0682E20 (Ver. 2.0) L CLK Command Address DQ tRCD WRIT ACT Pr Row Column in 0 Single write od t uc 25 EDS1616GGBH Auto Precharge Read with auto-precharge In this operation, since precharge is automatically performed after completing a read operation, a precharge command need not be executed after each read operation. The command executed for the same bank after the execution of this command must be the bank active (ACT) command. In addition, an interval defined by lAPR is required before execution of the next command. [Clock cycle time] /CAS latency 3 2 CLK Precharge start cycle 2 cycle before the final data is output 1 cycle before the final data is output EO CL=2 Command ACT DQ CL=3 Command ACT DQ READA lRAS out0 out1 out2 out3 ACT lAPR READA lRAS out0 out1 out2 out3 ACT Note: Internal auto-precharge starts at the timing indicated by " ". And an interval of tRAS (lRAS) is required between previous active (ACT) command and internal precharge " lAPR ". Write with auto-precharge In this operation, since precharge is automatically performed after completing a burst write or single write operation, a precharge command need not be executed after each write operation. The command executed for the same bank after the execution of this command must be the bank active (ACT) command. In addition, an interval of lDAL is required between the final valid data input and input of next command. Command Note: Internal auto-precharge starts at the timing indicated by " ". and an interval of tRAS (lRAS) is required between previous active (ACT) command and internal precharge " ". Preliminary Data Sheet E0682E20 (Ver. 2.0) L CLK ACT Burst Read (BL = 4) Pr WRITA ACT lRAS DQ Burst Write (BL = 4) od in0 in1 in2 in3 lDAL t uc 26 EDS1616GGBH CLK Command ACT ACT WRITA lRAS DQ in lDAL Note: Internal auto-precharge starts at the timing indicated by " ". and an interval of tRAS (lRAS) is required between previous active (ACT) command and internal precharge " ". EO Single Write Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr od t uc 27 EDS1616GGBH Burst Stop Command During a read cycle, when the burst stop command is issued, the burst read data are terminated and the data bus goes to High-Z after the /CAS latency from the burst stop command. CLK Command DQ (CL = 2) DQ (CL = 3) READ BST High-Z out out out out out out High-Z EO CLK Command DQ Burst Stop at Read During a write cycle, when the burst stop command is issued, the burst write data are terminated and data bus goes to High-Z at the same clock with the burst stop command. WRITE in in in in BST High-Z Preliminary Data Sheet E0682E20 (Ver. 2.0) L Burst Stop at Write Pr od t uc 28 EDS1616GGBH Command Intervals Read command to Read command interval 1. Same bank, same ROW address: When another read command is executed at the same ROW address of the same bank as the preceding read command execution, the second read can be performed after an interval of no less than 1 clock. Even when the first command is a burst read that is not yet finished, the data read by the second command will be valid. CLK Command Address BS ACT READ READ Row Column A Column B DQ EO CLK Command Address out A0 out B0 out B1 out B2 out B3 Column =A Column =B Column =A Column =B Dout Read Read Dout Bank0 Active CL = 3 BL = 4 Bank 0 READ to READ Command Interval (same ROW address in same bank) 2. Same bank, different ROW address: When the ROW address changes on same bank, consecutive read commands cannot be executed; it is necessary to separate the two read commands with a precharge command and a bank active command. 3. Different bank: When the bank changes, the second read can be performed after an interval of no less than 1 clock, provided that the other bank is in the bank active state. Even when the first command is a burst read that is not yet finished, the data read by the second command will be valid. BS DQ Bank0 Active Preliminary Data Sheet E0682E20 (Ver. 2.0) L ACT ACT Row 0 Row 1 READ READ Column A Column B READ to READ Command Interval (different bank) Pr Bank1 Bank0 Bank1 Active Read Read Bank0 Bank1 Dout Dout out A0 out B0 out B1 out B2 out B3 CL = 3 BL = 4 od t uc 29 EDS1616GGBH Write command to Write command interval 1. Same bank, same ROW address: When another write command is executed at the same ROW address of the same bank as the preceding write command, the second write can be performed after an interval of no less than 1 clock. In the case of burst writes, the second write command has priority. CLK Command Address ACT WRIT WRIT Row Column A Column B BS DQ in A0 Bank0 Active in B0 in B1 in B2 in B3 EO CLK Command ACT Column =A Column =B Write Write Burst Write Mode BL = 4 Bank 0 WRITE to WRITE Command Interval (same ROW address in same bank) 2. Same bank, different ROW address: When the ROW address changes, consecutive write commands cannot be executed; it is necessary to separate the two write commands with a precharge command and a bank active command. 3. Different bank: When the bank changes, the second write can be performed after an interval of no less than 1 clock, provided that the other bank is in the bank active state. In the case of burst write, the second write command has priority. Address BS DQ Bank0 Active Preliminary Data Sheet E0682E20 (Ver. 2.0) L ACT Row 0 Row 1 WRIT WRIT Column A Column B WRITE to WRITE Command Interval (different bank) Pr in A0 in B0 in B1 in B2 in B3 Bank1 Bank0 Bank1 Active Write Write Burst Write Mode BL = 4 od t uc 30 EDS1616GGBH Read command to Write command interval 1. Same bank, same ROW address: When the write command is executed at the same ROW address of the same bank as the preceding read command, the write command can be performed after an interval of no less than 1 clock. However, UDQM and LDQM must be set High so that the output buffer becomes High-Z before data input. CLK Command READ WRIT UDQM CL=2 LDQM CL=3 DQ (input) in B0 High-Z in B1 in B2 in B3 DQ (output) BL = 4 Burst write EO DQ READ to WRITE Command Interval (1) CLK READ WRIT Command UDQM LDQM CL=2 CL=3 2 clock out out out out out in in in in in in in in 2. Same bank, different ROW address: When the ROW address changes, consecutive write commands cannot be executed; it is necessary to separate the two commands with a precharge command and a bank active command. 3. Different bank: When the bank changes, the write command can be performed after an interval of no less than 1 cycle, provided that the other bank is in the bank active state. However, UDQM and LDQM must be set High so that the output buffer becomes High-Z before data input. Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr 31 READ to WRITE Command Interval (2) od t uc EDS1616GGBH Write command to Read command interval: 1. Same bank, same ROW address: When the read command is executed at the same ROW address of the same bank as the preceding write command, the read command can be performed after an interval of no less than 1 clock. However, in the case of a burst write, data will continue to be written until one clock before the read command is executed. CLK Command UDQM LDQM DQ (input) WRIT READ in A0 out B0 Column = A Write Column = B Read out B1 out B2 out B3 Burst Write Mode CL = 2 BL = 4 Bank 0 EO DQ (output) CLK Command UDQM LDQM DQ (input) DQ (output) /CAS Latency Column = B Dout WRITE to READ Command Interval (1) WRIT READ 2. Same bank, different ROW address: When the ROW address changes, consecutive read commands cannot be executed; it is necessary to separate the two commands with a precharge command and a bank active command. 3. Different bank: When the bank changes, the read command can be performed after an interval of no less than 1 clock, provided that the other bank is in the bank active state. However, in the case of a burst write, data will continue to be written until one clock before the read command is executed (as in the case of the same bank and the same address). Preliminary Data Sheet E0682E20 (Ver. 2.0) L in A0 Column = A Write in A1 out B0 out B1 out B2 out B3 Burst Write Mode CL = 2 BL = 4 Bank 0 Pr Column = B Read /CAS Latency Column = B Dout WRITE to READ Command Interval (2) od 32 t uc EDS1616GGBH Read with auto precharge to Read command interval 1. Different bank: When some banks are in the active state, the second read command (another bank) is executed. Even when the first read with auto-precharge is a burst read that is not yet finished, the data read by the second command is valid. The internal auto-precharge of one bank starts at the next clock of the second command. CLK Command BS DQ bank0 Read A bank1 Read ". out A0 out A1 out B0 out B1 CL= 3 BL = 4 READA READ Note: Internal auto-precharge starts at the timing indicated by " EO CLK Command BS DQ Read with Auto Precharge to Read Command Interval (Different bank) 2. Same bank: The consecutive read command (the same bank) is illegal. Write with auto precharge to Write command interval 1. Different bank: When some banks are in the active state, the second write command (another bank) is executed. In the case of burst writes, the second write command has priority. The internal auto-precharge of one bank starts 2 clocks later from the second command. Note: Internal auto-precharge starts at the timing indicated by " 2. Same bank: The consecutive write command (the same bank) is illegal. Preliminary Data Sheet E0682E20 (Ver. 2.0) L WRITA in A0 bank0 Write A in A1 WRIT in B0 bank1 Write in B1 in B2 in B3 BL= 4 Write with Auto Precharge to Write Command Interval (Different bank) Pr 33 ". od t uc EDS1616GGBH Read with auto precharge to Write command interval 1. Different bank: When some banks are in the active state, the second write command (another bank) is executed. However, UDQM and LDQM must be set High so that the output buffer becomes High-Z before data input. The internal auto-precharge of one bank starts at the next clock of the second command. CLK Command BS UDQM LDQM CL = 2 CL = 3 in B0 in B1 in B2 in B3 READA WRIT DQ (input) EO CLK Command BS UDQM LDQM DQ (input) DQ (output) DQ (output) bank0 ReadA bank1 Write High-Z BL = 4 ". Note: Internal auto-precharge starts at the timing indicated by " Read with Auto Precharge to Write Command Interval (Different bank) 2. Same bank: The consecutive write command from read with auto precharge (the same bank) is illegal. It is necessary to separate the two commands with a bank active command. Write with auto precharge to Read command interval 1. Different bank: When some banks are in the active state, the second read command (another bank) is executed. However, in case of a burst write, data will continue to be written until one clock before the read command is executed. The internal auto-precharge of one bank starts at 2 clocks later from the second command. 2. Same bank: The consecutive read command from write with auto precharge (the same bank) is illegal. It is necessary to separate the two commands with a bank active command. Preliminary Data Sheet E0682E20 (Ver. 2.0) L WRITA in A0 bank0 WriteA Note: Internal auto-precharge starts at the timing indicated by " Write with Auto Precharge to Read Command Interval (Different bank) Pr READ od out B0 out B1 out B2 out B3 CL = 3 BL = 4 ". bank1 Read t uc 34 EDS1616GGBH Read command to Precharge command interval (same bank) When the precharge command is executed for the same bank as the read command that preceded it, the minimum interval between the two commands is one clock. However, since the output buffer then becomes High-Z after the clocks defined by lHZP, there is a case of interruption to burst read data output will be interrupted, if the precharge command is input during burst read. To read all data by burst read, the clocks defined by lEP must be assured as an interval from the final data output to precharge command execution. CLK Command READ PRE/PALL DQ out A0 out A1 out A2 out A3 CL=2 lEP = -1 cycle EO CLK Command DQ CLK Command DQ CLK Command DQ READ to PRECHARGE Command Interval (same bank): To output all data (CL = 2, BL = 4) READ PRE/PALL out A0 out A1 out A2 out A3 READ to PRECHARGE Command Interval (same bank): To output all data (CL = 3, BL = 4) READ to PRECHARGE Command Interval (same bank): To stop output data (CL = 2, BL = 1, 2, 4, 8) READ to PRECHARGE Command Interval (same bank): To stop output data (CL = 3, BL = 1, 2, 4, 8) Preliminary Data Sheet E0682E20 (Ver. 2.0) L READ READ CL=3 lEP = -2 cycle Pr PRE/PALL High-Z out A0 lHZP = 2 PRE/PALL out A0 lHZP =3 od High-Z t uc 35 EDS1616GGBH Write command to Precharge command interval (same bank) When the precharge command is executed for the same bank as the write command that preceded it, the minimum interval between the two commands is 1 clock. However, if the burst write operation is unfinished, the input data must be masked by means of UDQM and LDQM for assurance of the clock defined by tDPL. CLK Command UDQM LDQM DQ in A0 in A1 in A2 WRIT PRE/PALL tDPL EO CLK Command UDQM LDQM DQ WRITE to PRECHARGE Command Interval (same bank) (BL = 4 (To stop write operation)) WRIT PRE/PALL WRITE to PRECHARGE Command Interval (same bank) (BL = 4 (To write all data)) Preliminary Data Sheet E0682E20 (Ver. 2.0) L in A0 in A1 in A2 in A3 tDPL Pr od t uc 36 EDS1616GGBH Bank active command interval 1. Same bank: The interval between the two bank active commands must be no less than tRC. 2. In the case of different bank active commands: The interval between the two bank active commands must be no less than tRRD. CLK Command ACT ACT Address ROW ROW BS tRC Bank 0 Active EO Bank 0 Active Bank Active to Bank Active for Same Bank CLK ACT ROW:0 ACT ROW:1 Command Address Mode register set to Bank active command interval The interval between setting the mode register and executing a bank active command must be no less than lMRD. CLK Preliminary Data Sheet E0682E20 (Ver. 2.0) L BS tRRD Bank 0 Active Bank 1 Active Command Address Mode register set to Bank active command interval Pr MRS OPCODE lMRD Mode Register Set Bank Active to Bank Active for Different Bank od ACT BS & ROW Bank Active t uc 37 EDS1616GGBH DQM Control The UDQM and LDQM mask the upper and lower bytes of the DQ data, respectively. The timing of UDQM and LDQM is different during reading and writing. Reading When data is read, the output buffer can be controlled by UDQM and LDQM. By setting UDQM and LDQM to Low, the output buffer becomes Low-Z, enabling data output. By setting UDQM and LDQM to High, the output buffer becomes High-Z, and the corresponding data is not output. However, internal reading operations continue. The latency of UDQM and LDQM during reading is 2 clocks. Writing Input data can be masked by UDQM and LDQM. By setting DQM to Low, data can be written. In addition, when UDQM and LDQM are set to High, the corresponding data is not written, and the previous data is held. The latency of UDQM and LDQM during writing is 0 clock. EO CLK UDQM LDQM DQ CLK UDQM LDQM DQ Preliminary Data Sheet E0682E20 (Ver. 2.0) High-Z out 0 out 1 out 3 lDOD = 2 Latency L in 0 Reading Pr in 1 lDID = 0 Latency in 3 od Writing t uc 38 EDS1616GGBH Refresh Auto-refresh All the banks must be precharged before executing an auto-refresh command. Since the auto-refresh command updates the internal counter every time it is executed and determines the banks and the ROW addresses to be refreshed, external address specification is not required. The refresh cycles are required to refresh all the ROW addresses within tREF (max.). The output buffer becomes High-Z after auto-refresh start. In addition, since a precharge has been completed by an internal operation after the auto-refresh, an additional precharge operation by the precharge command is not required. Self-refresh After executing a self-refresh command, the self-refresh operation continues while CKE is held Low. During selfrefresh operation, all ROW addresses are refreshed by the internal refresh timer. A self-refresh is terminated by a self-refresh exit command. Before and after self-refresh mode, execute auto-refresh to all refresh addresses in or within tREF (max.) period on the condition 1 and 2 below. 1. Enter self-refresh mode within time as below* after either burst refresh or distributed refresh at equal interval to all refresh addresses are completed. 2. Start burst refresh or distributed refresh at equal interval to all refresh addresses within time as below*after exiting from self-refresh mode. EO Others Note: tREF (max.) / refresh cycles. Power-down mode The SDRAM enters power-down mode when CKE goes Low in the IDLE state. In power down mode, power consumption is suppressed by deactivating the input initial circuit. Power down mode continues while CKE is held Low. In addition, by setting CKE to High, the SDRAM exits from the power down mode, and command input is enabled from the next clock. In this mode, internal refresh is not performed. Clock suspend mode By driving CKE to Low during a bank active or read/write operation, the SDRAM enters clock suspend mode. During clock suspend mode, external input signals are ignored and the internal state is maintained. When CKE is driven High, the SDRAM terminates clock suspend mode, and command input is enabled from the next clock. For details, refer to the "CKE Truth Table". Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr 39 od t uc EDS1616GGBH Timing Waveforms Read Cycle tCK tCH t CL CLK t RC VIH CKE tRCD tSI tHI tSI tHI tRAS tSI tHI t RP tSI tHI /CS tSI tHI tSI tHI tSI tHI tSI tHI /RAS tSI tHI tSI tHI tSI tHI tSI tHI EO /CAS /WE BS A10 Address DQM DQ (input) DQ (output) tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI Preliminary Data Sheet E0682E20 (Ver. 2.0) L tSI tAC t AC tOH Bank 0 Active Bank 0 Read tHI Pr tAC tAC tOH tOH tLZ Bank 0 Precharge tHZ tOH /CAS latency = 2 Burst length = 4 Bank 0 access = VIH or VIL = VOH or VOL od t uc 40 EDS1616GGBH Write Cycle tCK tCH tCL CLK tRC VIH CKE tRCD tSI tHI tSI tHI tSI tHI tSI tHI tRAS tRP /CS tSI tHI tSI tHI tSI tHI tSI tHI /RAS tSI tHI tSI tHI tSI tHI tSI tHI /CAS EO /WE BS A10 Address UDQM LDQM DQ (input) DQ (output) 0 tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI tHI tSI Mode Register Set Cycle 1 2 L tSI Bank 0 Active tHI t HI tSI tHI tSI tHI tSI tHI tDPL Pr Bank 0 Write Bank 0 Precharge CL = 2 BL = 4 Bank 0 access = VIH or VIL 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 CLK CKE /CS /RAS /CAS /WE BS Address UDQM LDQM DQ (output) DQ (input) lRP Precharge If needed od t uc b+3 b’ b’+1 b’+2 b’+3 lRCD = 3 /CAS latency = 3 Burst length = 4 = VIH or VIL code R: b C: b C: b’ b High-Z lMRD Mode register Set Bank 1 Active VIH valid lRCD Bank 1 Read Output mask Preliminary Data Sheet E0682E20 (Ver. 2.0) 41 EDS1616GGBH Read Cycle/Write Cycle 0 CLK CKE /CS /RAS /CAS /WE BS Address UDQM, LDQM VIH 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Read cycle /RAS-/CAS delay = 3 /CAS latency = 3 Burst length = 4 = VIH or VIL R:a C:a R:b a C:b a+1 a+2 a+3 Bank 1 Bank 0 Read Precharge C:b' b High-Z C:b" b'+1 b" b"+1 b"+2 b"+3 Bank 1 Precharge DQ (output) DQ (input) Bank 0 Active Bank 0 Read Bank 1 Active b+1 b+2 b+3 b' Bank 1 Read Bank 1 Read CKE /CS VIH /RAS /CAS /WE BS Write cycle /RAS-/CAS delay = 3 /CAS latency = 3 Burst length = 4 = VIH or VIL EO Address R:a UDQM, LDQM C:a R:b C:b High-Z C:b' C:b" DQ (output) DQ (input) a Bank 0 Write a+1 a+2 a+3 Bank 1 Active b Bank 1 Write b+1 b+2 b+3 b' Bank 0 Precharge Bank 1 Write b'+1 b" Bank 1 Write b"+1 b"+2 b"+3 Bank 1 Precharge Bank 0 Active Read/Single Write Cycle CLK CKE /CS /RAS /CAS /WE BS Address UDQM, LDQM DQ (input) DQ (output) Bank 0 Active CKE /CS /RAS /CAS /WE BS Address UDQM, LDQM DQ (input) DQ (output) Bank 0 Active Bank 0 Read Bank 1 Active Preliminary Data Sheet E0682E20 (Ver. 2.0) L 0 1 2 3 VIH 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Pr C:a R:b a Bank 0 Read Bank 1 Active R:a C:a' C:a a a+1 a+2 a+3 od a Bank 0 Bank 0 Write Read a+1 a+2 a+3 Bank 0 Precharge Bank 1 Precharge VIH t uc C:b C:c b c Bank 0 Bank 0 Write Write Bank 0 Precharge R:a C:a R:b C:a a a a+1 a+3 Bank 0 Write Read/Single write /RAS-/CAS delay = 3 /CAS latency = 3 Burst length = 4 = VIH or VIL 42 EDS1616GGBH Read/Burst Write Cycle 0 CLK CKE /CS /RAS /CAS /WE BS Address UDQM, LDQM DQ (input) DQ (output) a Bank 0 Read Bank 1 Active 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 R:a C:a R:b C:a' a a+1 a+2 a+3 Clock suspend a+1 a+2 a+3 Bank 0 Precharge Bank 1 Precharge EO Bank 0 Active Bank 0 Write CKE /CS VIH /RAS /CAS BS /WE Address R:a C:a R:b C:a a a a+1 a+3 Bank 0 Write Bank 0 Precharge L Bank 0 Active Bank 0 Read UDQM, LDQM DQ (input) DQ (output) a+1 a+2 a+3 Bank 1 Active Read/Burst write /RAS-/CAS delay = 3 /CAS latency = 3 Burst length = 4 = VIH or VIL Pr 3 4 5 6 7 8 9 10 11 High-Z Auto Refresh Cycle 0 1 2 12 13 14 15 16 17 18 19 20 CLK CKE /CS /RAS /CAS /WE BS Address UDQM LDQM A10=1 od R:a VIH C:a t uc a a+1 Active Bank 0 Read Bank 0 DQ (input) DQ (output) t RP Precharge If needed Auto Refresh t RC Auto Refresh t RC Refresh cycle and Read cycle /RAS-/CAS delay = 2 /CAS latency = 2 Burst length = 4 = VIH or VIL Preliminary Data Sheet E0682E20 (Ver. 2.0) 43 EDS1616GGBH Self Refresh Cycle CLK CKE /CS /RAS /CAS /WE BS Address A10=1 lSREX CKE Low UDQM LDQM EO DQ (input) DQ (output) High-Z t RP Self refresh entry command Self refresh exit ignore command or No operation t RC Next clock enable Self refresh entry command t RC Auto Next clock refresh enable Precharge command If needed Self refresh cycle /RAS-/CAS delay = 3 CL = 3 BL = 4 = VIH or VIL Clock Suspend Mode 0 tSI tHI tSI L 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 CLK CKE /CS /RAS /CAS /WE BS Address UDQM, LDQM DQ (output) DQ (input) Read cycle /RAS-/CAS delay = 2 /CAS latency = 2 Burst length = 4 = VIH or VIL Pr C:a R:b a a+1 a+2 High-Z Active clock Bank0 suspend end Read Bank1 Active Read suspend start Read suspend end R:a C:b b b+1 b+2 b+3 a+3 Bank0 Active clock Active suspend start Bank1 Read Bank0 Precharge Earliest Bank1 Precharge od C:b High-Z CKE /CS /RAS /CAS /WE BS Address UDQM, LDQM DQ (output) DQ (input) Bank0 Active Active clock suspend start Write cycle /RAS-/CAS delay = 2 /CAS latency = 2 Burst length = 4 = VIH or VIL R:a C:a R:b t uc Earliest Bank1 Precharge a a+1 a+2 Write suspend start a+3 b Write suspend end b+1 b+2 b+3 Active clock Bank0 Bank1 supend end Write Active Bank1 Bank0 Write Precharge Preliminary Data Sheet E0682E20 (Ver. 2.0) 44 EDS1616GGBH Power Down Mode CLK CKE /CS /RAS /CAS /WE BS Address A10=1 CKE Low R: a EO Initialization Sequence 0 1 UDQM LDQM High-Z DQ (input) DQ (output) tRP Precharge command If needed Power down entry Power down /RAS-/CAS delay = 3 mode exit Active Bank 0 /CAS latency = 3 Power down cycle Burst length = 4 = VIH or VIL L 2 3 4 VIH valid VIH tRP All banks Precharge Auto Refresh 5 6 7 8 9 10 48 49 50 51 52 53 54 55 CLK CKE /CS /RAS /CAS /WE Address Pr t RC Auto Refresh code Valid UDQM LDQM DQ High-Z tRC lMRD Bank active If needed od 45 Mode register Set t uc Preliminary Data Sheet E0682E20 (Ver. 2.0) EDS1616GGBH Package Drawing 60-ball FBGA Solder ball: Lead free (Sn-Ag-Cu) Unit: mm B 6.40 ± 0.10 INDEX MARK 0.15 S 2X FGHJ KLMNPR AB CDE 9.10 INDEX MARK 3.90 0.65 60-φ0.40±0.05 φ0.15 φ0.08 M M SAB S 0.65 EO 10.10 ± 0.10 Preliminary Data Sheet E0682E20 (Ver. 2.0) L A 0.10 S 12 ⁄⁄ 0.20 S 1.10 max. S Pr 67 0.29 ± 0.05 od t uc ECA-TS2-0112-01 46 EDS1616GGBH Recommended Soldering Conditions Please consult with our sales offices for soldering conditions of the EDS1616GGBH. Type of Surface Mount Device EDS1616GGBH: 60-ball FBGA< Lead free (Sn-Ag-Cu) > EO Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr od t uc 47 EDS1616GGBH N OTES FOR CMOS DEVICES 1 PRECAUTION AGAINST ESD FOR MOS DEVICES Exposing the MOS devices to a strong electric field can cause destruction of the gate oxide and ultimately degrade the MOS devices operation. Steps must be taken to stop generation of static electricity as much as possible, and quickly dissipate it, when once it has occurred. Environmental control must be adequate. When it is dry, humidifier should be used. It is recommended to avoid using insulators that easily build static electricity. MOS devices must be stored and transported in an anti-static container, static shielding bag or conductive material. All test and measurement tools including work bench and floor should be grounded. The operator should be grounded using wrist strap. MOS devices must not be touched with bare hands. Similar precautions need to be taken for PW boards with semiconductor MOS devices on it. HANDLING OF UNUSED INPUT PINS FOR CMOS DEVICES EO 2 3 No connection for CMOS devices input pins can be a cause of malfunction. If no connection is provided to the input pins, it is possible that an internal input level may be generated due to noise, etc., hence causing malfunction. CMOS devices behave differently than Bipolar or NMOS devices. Input levels of CMOS devices must be fixed high or low by using a pull-up or pull-down circuitry. Each unused pin should be connected to VDD or GND with a resistor, if it is considered to have a possibility of being an output pin. The unused pins must be handled in accordance with the related specifications. STATUS BEFORE INITIALIZATION OF MOS DEVICES Power-on does not necessarily define initial status of MOS devices. Production process of MOS does not define the initial operation status of the device. Immediately after the power source is turned ON, the MOS devices with reset function have not yet been initialized. Hence, power-on does not guarantee output pin levels, I/O settings or contents of registers. MOS devices are not initialized until the reset signal is received. Reset operation must be executed immediately after power-on for MOS devices having reset function. Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr 48 CME0107 od t uc EDS1616GGBH The information in this document is subject to change without notice. Before using this document, confirm that this is the latest version. No part of this document may be copied or reproduced in any form or by any means without the prior written consent of Elpida Memory, Inc. Elpida Memory, Inc. does not assume any liability for infringement of any intellectual property rights (including but not limited to patents, copyrights, and circuit layout licenses) of Elpida Memory, Inc. or third parties by or arising from the use of the products or information listed in this document. No license, express, implied or otherwise, is granted under any patents, copyrights or other intellectual property rights of Elpida Memory, Inc. or others. Descriptions of circuits, software and other related information in this document are provided for illustrative purposes in semiconductor product operation and application examples. The incorporation of these circuits, software and information in the design of the customer's equipment shall be done under the full responsibility of the customer. Elpida Memory, Inc. assumes no responsibility for any losses incurred by customers or third parties arising from the use of these circuits, software and information. [Product applications] Elpida Memory, Inc. makes every attempt to ensure that its products are of high quality and reliability. However, users are instructed to contact Elpida Memory's sales office before using the product in aerospace, aeronautics, nuclear power, combustion control, transportation, traffic, safety equipment, medical equipment for life support, or other such application in which especially high quality and reliability is demanded or where its failure or malfunction may directly threaten human life or cause risk of bodily injury. [Product usage] Design your application so that the product is used within the ranges and conditions guaranteed by Elpida Memory, Inc., including the maximum ratings, operating supply voltage range, heat radiation characteristics, installation conditions and other related characteristics. Elpida Memory, Inc. bears no responsibility for failure or damage when the product is used beyond the guaranteed ranges and conditions. Even within the guaranteed ranges and conditions, consider normally foreseeable failure rates or failure modes in semiconductor devices and employ systemic measures such as fail-safes, so that the equipment incorporating Elpida Memory, Inc. products does not cause bodily injury, fire or other consequential damage due to the operation of the Elpida Memory, Inc. product. [Usage environment] This product is not designed to be resistant to electromagnetic waves or radiation. This product must be used in a non-condensing environment. If you export the products or technology described in this document that are controlled by the Foreign Exchange and Foreign Trade Law of Japan, you must follow the necessary procedures in accordance with the relevant laws and regulations of Japan. Also, if you export products/technology controlled by U.S. export control regulations, or another country's export control laws or regulations, you must follow the necessary procedures in accordance with such laws or regulations. If these products/technology are sold, leased, or transferred to a third party, or a third party is granted license to use these products, that third party must be made aware that they are responsible for compliance with the relevant laws and regulations. EO Preliminary Data Sheet E0682E20 (Ver. 2.0) L Pr 49 M01E0107 od t uc