1M 4 BANKS 16 BITS SDRAM

Transcription

1 1M 4 BANKS 16 BITS SDRAM Table of Contents- 1. GENERAL DESCRIPTION FEATURES ORDER INFORMATION BALL CONFIGURATION BALL DESCRIPTION BLOCK DIAGRAM FUNCTIONAL DESCRIPTION Power Up and Initialization Programming Mode Register Bank Activate Command and Access Modes Burst Command Burst Command Interrupted by a Interrupted by a Interrupted by a Interrupted by a Burst Stop Command Addressing Sequence of Sequential Mode Addressing Sequence of Interleave Mode Auto-precharge Command Precharge Command Self Refresh Command Power Down Mode No Operation Command Deselect Command Clock Suspend Mode OPERATION MODE ELECTRICAL CHARACTERISTICS Absolute Maimum Ratings Recommended DC Operating Conditions Revision: A03

2 9.3 Capacitance DC Characteristics AC Characteristics and Operating Condition TIMING WAVEFORMS Command Input Timing Timing Control Timing of Input/Output Data Mode Register Set Cycle OPERATING TIMING EXAMPLE Interleaved Bank (Burst Length = 4, CAS Latency = 3) Interleaved Bank (Burst Length = 4, CAS Latency = 3, Auto-precharge) Interleaved Bank (Burst Length = 8, CAS Latency = 3) Interleaved Bank (Burst Length = 8, CAS Latency = 3, Auto-precharge) Interleaved Bank (Burst Length = 8) Interleaved Bank (Burst Length = 8, Auto-precharge) Page Mode (Burst Length = 4, CAS Latency = 3) Page Mode / (Burst Length = 8, CAS Latency = 3) Auto Precharge (Burst Length = 4, CAS Latency = 3) Auto Precharge (Burst Length = 4) Auto Refresh Cycle Self Refresh Cycle Burst and Single (Burst Length = 4, CAS Latency = 3) Power down Mode Auto-precharge Timing ( Cycle) Auto-precharge Timing ( Cycle) Timing Chart of to Cycle Timing Chart of to Cycle Timing Chart of Burst Stop Cycle (Burst Stop Command) Timing Chart of Burst Stop Cycle (Precharge Command) /M Input Timing ( Cycle) /M Input Timing ( Cycle) PACKAGE SPECIFICATION REVISION HISTORY Revision: A03

3 1. GENERAL DESCRIPTION W9864G6JT is a high-speed synchronous dynamic random access memory (SDRAM), organized as 1M words 4 banks 16 bits. W9864G6JT delivers a data bandwidth of up to 166M words per second. W9864G6JT is sorted into too speed grades: -6 and -6I. They are compliant to the 166MHz/CL3 specification (-6I industrial grade which is guaranteed to support -40 C TA 85 C). Accesses to the SDRAM are burst oriented. Consecutive memory location in one page can be accessed at a burst length of 1, 2, 4, 8 or full page when a bank and row is selected by an ACTIVE command. Column addresses are automatically generated by the SDRAM internal counter in burst operation. Random column read is also possible by providing its address at each clock cycle. The multiple bank nature enables interleaving among internal banks to hide the precharging time. By having a programmable Mode Register, the system can change burst length, latency cycle, interleave or sequential burst to maimize its performance. W9864G6JT is ideal for main memory in high performance applications. 2. FEATURES 3.3V ± 0.3V Power Supply Up to 166 MHz Clock Frequency 1,048,576 Words 4 banks 16 bits organization Self Refresh Mode CAS Latency: 2 and 3 Burst Length: 1, 2, 4, 8 and full page Sequential and Interleave Burst Burst, Single s Mode Byte Data Controlled by LM, UM Power Down Mode Auto-precharge and Controlled Precharge 4K Refresh cycles/64 ms Interface: LVTTL Packaged in TFBGA 54 Ball (88 mm 2 ), using lead free materials with RoHS compliant 3. ORDER INFORMATION PART NUMBER SPEED SELF REFRESH CURRENT (MAX.) OPERATING TEMPERATURE W9864G6JT-6 166MHz/CL3 2 ma 0 C ~ 70 C W9864G6JT-6I 166MHz/CL3 2 ma -40 C ~ 85 C Revision: A03

4 4. BALL CONFIGURATION Top View A B C D E F G H J VSS UM NC A8 VSS NC A11 A7 A5 VSSQ VD VSSQ VD VSS A9 A6 A4 VD VSSQ VD VSSQ VDD /CAS BS0 A0 A LM /RAS BS1 A1 A2 VDD /WE /CS A10 VDD Revision: A03

5 5. BALL DESCRIPTION BALL LOCATION BALL NAME FUNCTION DESCRIPTION H7, H8, J8, J7, J3, J2, H3, H2, H1, G3, H9, G2 A0 A11 Address G7, G8 BS0, BS1 Bank Select A8, B9, B8, C9, C8, D9, D8, E9, E1, D2, D1, C2, C1, B2, B1, A Data Input/ Output G9 CS Chip Select F8 F7 RAS CAS Row Address Strobe Column Address Strobe Multipleed pins for row and column address. Row address: A0 A11. Column address: A0 A7. A10 is sampled during a precharge command to determine if all banks are to be precharged or bank selected by BS0, BS1. Select bank to activate during row address latch time, or bank to read/write during address latch time. Multipleed pins for data output and input. Disable or enable the command decoder. When command decoder is disabled, new command is ignored and previous operation continues. Command input. When sampled at the rising edge of the clock RAS, CAS and WE define the operation to be eecuted. Referred to RAS F9 WE Enable Referred to RAS F1, E8 UM, LM Input/output mask F2 Clock Inputs F3 Clock Enable A9, E7, J9 VDD Power A1, E3, J1 VSS Ground A7, B3, C7, D3 VD A3, B7, C3, D7 VSSQ Power for I/O buffer Ground for I/O buffer E2, G1 NC No Connection No connection. The output buffer is placed at Hi-Z (with latency of 2) when M is sampled high in read cycle. In write cycle, sampling M high will block the write operation with zero latency. System clock used to sample inputs on the rising edge of clock. controls the clock activation and deactivation. When is low, Power Down mode, Suspend mode, or Self Refresh mode is entered. Power for input buffers and logic circuit inside DRAM. Ground for input buffers and logic circuit inside DRAM. Separated power from VDD, to improve noise immunity. Separated ground from VSS, to improve noise immunity Revision: A03

6 6. BLOCK DIAGRAM CLOCK BUFFER CS RAS COMMAND CONTROL SIGNAL GENERATOR CAS WE DECODER COLUMN DECODER COLUMN DECODER A10 A0 A9 A11 BS0 BS1 ADDRESS BUFFER REFRESH COUNTER MODE REGISTER COLUMN COUNTER ROW DECODER ROW DECODER CELL ARRAY BANK #0 SENSE AMPLIFIER COLUMN DECODER DATA CONTROL CIRCUIT CELL ARRAY BANK #2 ROW DECODER ROW DECODER CELL ARRAY BANK #1 SENSE AMPLIFIER BUFFER COLUMN DECODER CELL ARRAY BANK # UM LM SENSE AMPLIFIER SENSE AMPLIFIER NOTE: The cell array configuration is 4096 * 256 * Revision: A03

7 7. FUNCTIONAL DESCRIPTION 7.1 Power Up and Initialization The default power up state of the mode register is unspecified. The following power up and initialization sequence need to be followed to guarantee the device being preconditioned to each user specific needs. During power up, all VDD and VD pins must be ramp up simultaneously to the specified voltage when the input signals are held in the NOP state. The power up voltage must not eceed VDD +0.3V on any of the input pins or VDD supplies. After power up, an initial pause of 200 µs is required followed by a precharge of all banks using the precharge command. To prevent data contention on the bus during power up, it is required that the M and pins be held high during the initial pause period. Once all banks have been precharged, the Mode Register Set Command must be issued to initialize the Mode Register. An additional eight Auto Refresh cycles (CBR) are also required before or after programming the Mode Register to ensure proper subsequent operation. 7.2 Programming Mode Register After initial power up, the Mode Register Set Command must be issued for proper device operation. All banks must be in a precharged state and must be high at least one cycle before the Mode Register Set Command can be issued. The Mode Register Set Command is activated by the low signals of RAS, CAS, CS and WE at the positive edge of the clock. The address input data during this cycle defines the parameters to be set as shown in the Mode Register Operation table. A new command may be issued following the mode register set command once a delay equal to trsc has elapsed. Please refer to the net page for Mode Register Set Cycle and Operation Table. 7.3 Bank Activate Command The Bank Activate command must be applied before any or operation can be eecuted. The operation is similar to RAS activate in EDO DRAM. The delay from when the Bank Activate command is applied to when the first read or write operation can begin must not be less than the RAS to CAS delay time (trcd). Once a bank has been activated it must be precharged before another Bank Activate command can be issued to the same bank. The minimum time interval between successive Bank Activate commands to the same bank is determined by the RAS cycle time of the device (trc). The minimum time interval between interleaved Bank Activate commands (Bank A to Bank B and vice versa) is the Bank to Bank delay time (trrd). The maimum time that each bank can be held active is specified as tras (ma). 7.4 and Access Modes After a bank has been activated, a read or write cycle can be followed. This is accomplished by setting RAS high and CAS low at the clock rising edge after minimum of trcd delay. WE pin voltage level defines whether the access cycle is a read operation ( WE high), or a write operation ( WE low). The address inputs determine the starting column address. ing or writing to a different row within an activated bank requires the bank be precharged and a new Bank Activate command be issued. When more than one bank is activated, interleaved bank or operations are possible. By using the programmed burst length and alternating the access and precharge operations between multiple banks, seamless data access operation among many different pages can be realized. or Commands can also be issued to the same bank or between active banks on every clock cycle Revision: A03

8 7.5 Burst Command The Burst command is initiated by applying logic low level to CS and CAS while holding RAS and WE high at the rising edge of the clock. The address inputs determine the starting column address for the burst. The Mode Register sets type of burst (sequential or interleave) and the burst length (1, 2, 4, 8, full page) during the Mode Register Set Up cycle. Table 2 and 3 in the net page eplain the address sequence of interleave mode and sequential mode. 7.6 Burst Command The Burst command is initiated by applying logic low level to CS, CAS and WE while holding RAS high at the rising edge of the clock. The address inputs determine the starting column address. Data for the first burst write cycle must be applied on the pins on the same clock cycle that the Command is issued. The remaining data inputs must be supplied on each subsequent rising clock edge until the burst length is completed. Data supplied to the pins after burst finishes will be ignored. 7.7 Interrupted by a A Burst may be interrupted by another Command. When the previous burst is interrupted, the remaining addresses are overridden by the new read address with the full burst length. The data from the first Command continues to appear on the outputs until the CAS Latency from the interrupting Command the is satisfied. 7.8 Interrupted by a To interrupt a burst read with a Command, M may be needed to place the s (output drivers) in a high impedance state to avoid data contention on the bus. If a Command will issue data on the first and second clocks cycles of the write operation, M is needed to insure the s are tri-stated. After that point the Command will have control of the bus and M masking is no longer needed. 7.9 Interrupted by a A burst write may be interrupted before completion of the burst by another Command. When the previous burst is interrupted, the remaining addresses are overridden by the new address and data will be written into the device until the programmed burst length is satisfied Interrupted by a A Command will interrupt a burst write operation on the same clock cycle that the Command is activated. The s must be in the high impedance state at least one cycle before the new read data appears on the outputs to avoid data contention. When the Command is activated, any residual data from the burst write cycle will be ignored Revision: A03

9 7.11 Burst Stop Command A Burst Stop Command may be used to terminate the eisting burst operation but leave the bank open for future or Commands to the same page of the active bank, if the burst length is full page. Use of the Burst Stop Command during other burst length operations is illegal. The Burst Stop Command is defined by having RAS and CAS high with CS and WE low at the rising edge of the clock. The data s go to a high impedance state after a delay which is equal to the CAS Latency in a burst read cycle interrupted by Burst Stop Addressing Sequence of Sequential Mode A column access is performed by increasing the address from the column address which is input to the device. The disturb address is varied by the Burst Length as shown in Table 2. Table 2 Address Sequence of Sequential Mode DATA ACCESS ADDRESS BURST LENGTH Data 0 n BL = 2 (disturb address is A0) Data 1 n + 1 No address carry from A0 to A1 Data 2 n + 2 BL = 4 (disturb addresses are A0 and A1) Data 3 n + 3 No address carry from A1 to A2 Data 4 n + 4 Data 5 n + 5 BL = 8 (disturb addresses are A0, A1 and A2) Data 6 n + 6 No address carry from A2 to A3 Data 7 n Addressing Sequence of Interleave Mode A column access is started in the input column address and is performed by inverting the address bit in the sequence shown in Table 3. Table 3 Address Sequence of Interleave Mode DATA ACCESS ADDRESS BURST LENGTH Data 0 A8 A7 A6 A5 A4 A3 A2 A1 A0 BL = 2 Data 1 A8 A7 A6 A5 A4 A3 A2 A1 A0 Data 2 A8 A7 A6 A5 A4 A3 A2 A1 A0 BL = 4 Data 3 A8 A7 A6 A5 A4 A3 A2 A1 A0 Data 4 A8 A7 A6 A5 A4 A3 A2 A1 A0 BL = 8 Data 5 Data 6 Data 7 A8 A7 A6 A5 A4 A3 A2 A1 A0 A8 A7 A6 A5 A4 A3 A2 A1 A0 A8 A7 A6 A5 A4 A3 A2 A1 A0-9 - Revision: A03

10 7.14 Auto-precharge Command If A10 is set to high when the or Command is issued, then the Auto-precharge function is entered. During Auto-precharge, a Command will eecute as normal with the eception that the active bank will begin to precharge automatically before all burst read cycles have been completed. Regardless of burst length, it will begin a certain number of clocks prior to the end of the scheduled burst cycle. The number of clocks is determined by CAS Latency. A or Command with Auto-precharge can not be interrupted before the entire burst operation is completed. Therefore, use of a, or Precharge Command is prohibited during a read or write cycle with Auto-precharge. Once the precharge operation has started, the bank cannot be reactivated until the Precharge time () has been satisfied. Issue of Auto-precharge command is illegal if the burst is set to full page length. If A10 is high when a Command is issued, the with Auto-precharge function is initiated. The SDRAM automatically enters the precharge operation two clocks delay from the last burst write cycle. This delay is referred to as twr. The bank undergoing Auto-precharge can not be reactivated until twr and are satisfied. This is referred to as tdal, Data-in to delay (tdal = twr + ). When using the Auto-precharge Command, the interval between the Bank Activate Command and the beginning of the internal precharge operation must satisfy tras (min) Precharge Command The Precharge Command is used to precharge or close a bank that has been activated. The Precharge Command is entered when CS, RAS and WE are low and CAS is high at the rising edge of the clock. The Precharge Command can be used to precharge each bank separately or all banks simultaneously. Three address bits, A10, BS0, and BS1, are used to define which bank(s) is to be precharged when the command is issued. After the Precharge Command is issued, the precharged bank must be reactivated before a new read or write access can be eecuted. The delay between the Precharge Command and the Activate Command must be greater than or equal to the Precharge time () Self Refresh Command The Self Refresh Command is defined by having CS, RAS, CAS and held low with WE high at the rising edge of the clock. All banks must be idle prior to issuing the Self Refresh Command. Once the command is registered, must be held low to keep the device in Self Refresh mode. When the SDRAM has entered Self Refresh mode all of the eternal control signals, ecept, are disabled. The clock is internally disabled during Self Refresh Operation to save power. The device will eit Self Refresh operation after is returned high. Any subsequent commands can be issued after txsr from the end of Self Refresh Command. If, during normal operation, AUTO REFRESH cycles are issued in bursts (as opposed to being evenly distributed), a burst of 4,096 AUTO REFRESH cycles should be completed just prior to entering and just after eiting the self refresh mode Revision: A03

11 7.17 Power Down Mode The Power Down mode is initiated by holding low. All of the receiver circuits ecept are gated off to reduce the power. The Power Down mode does not perform any refresh operations, therefore the device can not remain in Power Down mode longer than the Refresh period (tref) of the device. The Power Down mode is eited by bringing high. When goes high, a No Operation Command is required on the net rising clock edge, depending on tck. The input buffers need to be enabled with held high for a period equal to tcks (min) + tck (min) No Operation Command The No Operation Command should be used in cases when the SDRAM is in a idle or a wait state to prevent the SDRAM from registering any unwanted commands between operations. A No Operation Command is registered when CS is low with RAS, CAS, and WE held high at the rising edge of the clock. A No Operation Command will not terminate a previous operation that is still eecuting, such as a burst read or write cycle Deselect Command The Deselect Command performs the same function as a No Operation Command. Deselect Command occurs when CS is brought high, the RAS, CAS, and WE signals become don t cares Clock Suspend Mode During normal access mode, must be held high enabling the clock. When is registered low while at least one of the banks is active, Clock Suspend Mode is entered. The Clock Suspend mode deactivates the internal clock and suspends any clocked operation that was currently being eecuted. There is a one clock delay between the registration of low and the time at which the SDRAM operation suspends. While in Clock Suspend mode, the SDRAM ignores any new commands that are issued. The Clock Suspend mode is eited by bringing high. There is a one clock cycle delay from when returns high to when Clock Suspend mode is eited Revision: A03

12 8. OPERATION MODE Fully synchronous operations are performed to latch the commands at the positive edges of. Table 1 shows the truth table for the operation commands. Table 1 Truth Table (Note (1), (2)) COMMAND DEVICE STATE n-1 n M BS0, 1 A10 A0 A9 A11 CS RAS CAS WE Bank Idle H v v v L L H H Bank Precharge Any H v L L L H L Precharge All Any H H L L H L (3) H v L v L H L L with Auto-precharge (3) H v H v L H L L (3) H v L v L H L H with Auto-precharge (3) H v H v L H L H Mode Register Set Idle H v v v L L L L No Operation Any H L H H H Burst Stop (4) H L H H L Device Deselect Any H H Auto - Refresh Idle H H L L L H Self - Refresh Entry Idle H L L L L H Self Refresh Eit idle (S.R.) L L H H Clock suspend Mode Entry H L X Power Down Mode Entry Idle (5) H H L L X Clock Suspend Mode Eit L H H L H L H H H H Power Down Mode Eit Any (power down) L L H H H L H H Data write/output Enable H L Data /Output Disable H H Notes: (1) v = valid = Don t care L = Low Level H = High Level (2) n signal is input level when commands are provided. n-1 signal is the input level one clock cycle before the command is issued. (3) These are state of bank designated by BS0, BS1 signals. (4) Device state is full page burst operation. (5) Power Down Mode can not be entered in the burst cycle. When this command asserts in the burst cycle, device state is clock suspend mode Revision: A03

13 9. ELECTRICAL CHARACTERISTICS 9.1 Absolute Maimum Ratings PARAMETER SYMBOL RATING UNIT NOTES Voltage on any pin relative to VSS VIN, VOUT -0.5 ~ VDD ( 4.6V ma.) V 1 Voltage on VDD/VD supply relative to VSS VDD, VD -0.5 ~ 4.6 V 1 Operating Temperature for -6 TA 0 ~ 70 C 1 Operating Temperature for -6I TA -40 ~ 85 C 1 Storage Temperature TSTG -55 ~ 150 C 1 Soldering Temperature (10s) TSOLDER 260 C 1 Power Dissipation PD 1 W 1 Short Circuit Output Current IOUT 50 ma 1 Note: 1. Eposure to conditions beyond those listed under Absolute Maimum Ratings may adversely affect the life and reliability of the device 9.2 Recommended DC Operating Conditions PARAMETER SYM. MIN. TYP. MAX. UNIT NOTES Power Supply Voltage VDD V 2 Power Supply Voltage (for I/O Buffer) VD V 2 Input High Voltage VIH VDD V 2 Input Low Voltage VIL V 2 Note: VIH(ma) = VDD/ VD+1.5V for pulse width 5 ns VIL(min) = VSS/ VSSQ-1.5V for pulse width 5 ns 9.3 Capacitance (VDD = 3.3V ± 0.3V, f = 1 MHz, TA = 25 C) Input Capacitance PARAMETER SYM. MIN. MAX. UNIT (A0 to A11, BS0, BS1, CS, RAS, CAS, WE, ) Ci pf Input Capacitance () C pf Input/Output Capacitance (0 15) Co pf Input Capacitance M Ci pf Note: These parameters are periodically sampled and not 100% tested Revision: A03

14 9.4 DC Characteristics (VDD = 3.3V ± 0.3V, TA = 0 to 70 C for -6, TA = -40 to 85 C for -6I) PARAMETER SYM. MAX. -6/-6I UNIT NOTES Operating Current tck = min., trc = min. precharge command cycling without burst operation Standby Current tck = min., CS = VIH VIH /L = VIH (min.) / VIL (ma.) Bank: inactive state Standby Current = VIL, CS = VIH VIH/L = VIH (min.) / VIL (ma.) Bank: inactive state No Operating Current tck = min., CS = VIH (min.) Bank: active state (4 Banks) Burst Operating Current (tck = min.) / command cycling Auto Refresh Current (tck = min.) Auto refresh command cycling Self Refresh Current ( = 0.2V) Self refresh mode 1 Bank Operation IDD = VIH IDD = VIL (Power Down mode) = VIH IDD2S 12 = VIL (Power Down mode) IDD2P 2 3 IDD2PS 2 ma = VIH IDD3 35 = VIL (Power Down mode) IDD3P 12 IDD4 75 3, 4 IDD IDD6 2 PARAMETER SYM. MIN. MAX. UNIT NOTES Input Leakage Current (0V VIN VDD, all other pins not under test = 0V) Output Leakage Current (Output disable, 0V VOUT VD) LVTTL Output H Level Voltage (IOUT = -2 ma) LVTTL Output L Level Voltage (IOUT = 2 ma ) II(L) -5 5 µa IO(L) -5 5 µa VOH V VOL V Revision: A03

15 9.5 AC Characteristics and Operating Condition (VDD = 3.3V ± 0.3V, TA = 0 to 70 C for -6, TA = -40 to 85 C for -6I) (Notes: 5, 6) -6/-6I PARAMETER SYM. MIN. MAX. Ref/ to Ref/ Command Period trc 60 to Precharge Command Period tras to / Command Delay Time trcd 15 UNIT ns NOTES /(a) to /(b)command Period tccd 1 tck Precharge to (b) Command Period 15 ns (a) to (b) Command Period trrd 12 Recovery Time Cycle Time CL* = 2 2 twr CL* = 3 2 CL* = Output Data Hold Time toh 3 9 Output Data High Impedance Time thz 6 7 Output Data Low Impedance Time tlz 0 9 Power Down Mode Entry Time tsb 6 ns Transition Time of (Rise and Fall) tt 1 Data-in-Set-up Time tds Data-in Hold Time tdh 1 8 Address Set-up Time tas Address Hold Time tah 1 8 Set-up Time tcks Hold Time tckh 1 8 Command Set-up Time tcms Command Hold Time tcmh 1 8 Refresh Time (4K/Refresh Cycles) tref 64 ms Mode Register Set Cycle Time trsc 2 tck Eit self refresh to ACTIVE command txsr 72 ns *CL = CAS Latency tck CL* = High Level Width tch 2 8 Low Level Width tcl 2 8 Access Time from CL* = 2 6 CL* = 3 5 tck Revision: A03

16 Notes: 1. Operation eceeds Absolute Maimum Ratings may cause permanent damage to the devices. 2. All voltages are referenced to VSS. 3. These parameters depend on the cycle rate and listed values are measured at a cycle rate with the minimum values of tck and trc. 4. These parameters depend on the output loading conditions. Specified values are obtained with output open. 5. Power up sequence is further described in the Functional Description section. 6. AC test load diagram. 1.4 V 50 ohms output Z = 50 ohms 30pF AC TEST LOAD 7. thz defines the time at which the outputs achieve the open circuit condition and is not referenced to output level. 8. Assumed input rise and fall time (tt) = 1nS. If tr & tf is longer than 1nS, transient time compensation should be considered, i.e., [(tr + tf)/2-1]ns should be added to the parameter. 9. If clock rising time (tt) is longer than 1nS, (tt/2-0.5)ns should be added to the parameter Revision: A03

17 10. TIMING WAVEFORMS 10.1 Command Input Timing tck tcl tch VIH VIL tcms tcmh tcmh tt tt tcms CS tcms tcmh RAS tcms tcmh CAS tcms tcmh WE tas tah A0-A11 BS0,1 tcks tckh tcks tckh tcks tckh Revision: A03

18 10.2 Timing CAS Latency CS RAS CAS WE A0-A11 BS0,1 tlz toh toh thz Valid Data-Out Valid Data-Out Command Burst Length Revision: A03

19 10.3 Control Timing of Input/Output Data Control Timing of Input Data (Word Mask) tcmh tcms tcmh tcms M tds tdh tds tdh tds tdh tds tdh 0~15 Valid Data-in Valid Data-in Valid Data-in Valid Data-in (Clock Mask) tckh tcks tckh tcks tds tdh tds tdh tds tdh tds tdh 0~15 Valid Data-in Valid Data-in Valid Data-in Valid Data-in Control Timing of Output Data (Output Enable) tcmh tcms tcmh tcms M toh toh thz toh tlz toh 0~15 Valid Data-Out Valid Data-Out OPEN Valid Data-Out (Clock Mask) tckh tcks tckh tcks toh toh toh toh 0~15 Valid Data-Out Valid Data-Out Valid Data-Out Revision: A03

20 10.4 Mode Register Set Cycle trsc tcms tcmh CS tcms tcmh RAS tcms tcmh CAS tcms tcmh WE A0-A11 BS0,1 tas tah Register set data A0 A1 A2 A3 A4 A5 A6 A0 A7 A8 A9 A10 A11 A0 BS0 "0" "0" "0" "0" "0" BS1 "0" Burst Length Addressing Mode CAS Latency (Test Mode) Reserved A0 Mode Reserved * "Reserved" should stay "0" during MRS cycle. net command A2 A1 A0 A0 0 A A A A A A A A0 1 1 Burst Length Sequential Interleave Reserved Full Page A0 A3 Addressing Mode 0 Sequential 1 Interleave A6 A5 A0 A4 0 A A A A A0 0 0 CAS Latency Reserved Reserved 2 3 Reserved Reserved A0 A9 Single Mode 0 Burst read and Burst write 1 Burst read and single write Revision: A03

21 11. OPERATING TIMING EXAMPLE 11.1 Interleaved Bank (Burst Length = 4, CAS Latency = 3) CS trc trc trc trc RAS tras tras CAS tras tras WE BS0 BS1 A10 trcd trcd trcd trcd RAa RBb RAc RBd RAe A0-A9, A11 RAa CAw RBb CB RAc CAy RBd CBz RAe M aw0 aw1 aw2 aw3 b0 b1 b2 b3 cy0 cy1 cy2 cy3 trrd trrd trrd trrd Bank #0 Precharge Precharge Bank #1 Precharge Bank #2 Bank #3 Idle Revision: A03

22 11.2 Interleaved Bank (Burst Length = 4, CAS Latency = 3, Auto-precharge) CS trc trc RAS trc trc tras tras tras CAS WE BS0 BS1 trcd trcd trcd trcd A10 RAa RBb RAc RBd RAe A0-A9, A11 RAa CAw RBb CB RAc CAy RBd CBz RAe M aw0 aw1 aw2 aw3 b0 b1 b2 b3 cy0 cy1 cy2 cy3 dz0 trrd trrd trrd trrd Bank #0 AP* AP* Bank #1 AP* Bank #2 Bank #3 Idle * AP is the internal precharge start timing Revision: A03

23 11.3 Interleaved Bank (Burst Length = 8, CAS Latency = 3) CS trc RAS tras tras CAS WE BS0 BS1 trcd trcd trcd A10 RAa RBb RAc A0-A9, A11 RAa CA RBb CBy RAc CAz M a0 a1 a2 a3 a4 a5 a6 by0 by1 by4 by5 by6 by7 CZ0 trrd trrd Bank #0 Precharge Bank #1 Bank #2 Idle Bank #3 Precharge Precharge Revision: A03

24 11.4 Interleaved Bank (Burst Length = 8, CAS Latency = 3, Auto-precharge) CS trc RAS tras tras tras CAS WE BS0 BS1 trcd trcd trcd A10 RAa RBb RAc A0-A9, A11 RAa CA RBb CBy RAc CAz M a0 a1 a2 a3 a4 a5 a6 a7 by0 by1 by4 by5 by6 CZ0 trrd trrd Bank #0 AP* Bank #1 AP* Bank #2 Idle Bank #3 * AP is the internal precharge start timing Revision: A03

25 11.5 Interleaved Bank (Burst Length = 8) CS trc RAS tras tras CAS trcd trcd trcd WE BS0 BS1 A10 RAa RBb RAc A0-A9, A11 RAa CA RBb CBy RAc CAz M a0 a1 a4 a5 a6 a7 by0 by1 by2 by3 by4 by5 by6 by7 CZ0 CZ1 CZ2 trrd trrd Bank #0 Precharge Bank #1 Bank #2 Bank #3 Idle Precharge Revision: A03

26 11.6 Interleaved Bank (Burst Length = 8, Auto-precharge) CS trc RAS tras tras CAS WE BS0 BS1 trcd trcd trcd A10 RAa RBb RAb A0-A9, A11 RAa CA RBb CBy RAc CAz M a0 a1 a4 a5 a6 a7 by0 by1 by2 by3 by4 by5 by6 by7 CZ0 CZ1 CZ2 trrd trrd Bank #0 Bank #1 AP* AP* Bank #2 Bank #3 Idle * AP is the internal precharge start timing Revision: A03

27 11.7 Page Mode (Burst Length = 4, CAS Latency = 3) CS tccd tccd tccd tras RAS tras CAS WE BS0 BS1 trcd trcd A10 RAa RBb A0-A9, A11 RAa CAI RBb CB CAy CAm CBz M a0 a1 a2 a3 b0 b1 Ay0 Ay1 Ay2 am0 am1 am2 bz0 bz1 bz2 bz3 trrd Bank #0 Precharge Bank #1 AP* Bank #2 Bank #3 Idle * AP is the internal precharge start timing Revision: A03

28 11.8 Page Mode / (Burst Length = 8, CAS Latency = 3) CS tras RAS CAS WE BS0 BS1 trcd A10 RAa A0-A9, A11 RAa CA CAy M twr a0 a1 a2 a3 a4 a5 ay0 ay1 ay2 ay3 ay4 Q Q Q Q Q Q D D D D D Bank #0 Bank #1 Bank #2 Bank #3 Precharge Idle Revision: A03

29 11.9 Auto Precharge (Burst Length = 4, CAS Latency = 3) CS trc RAS tras tras CAS WE BS0 BS1 A10 RAa trcd RAb trcd A0-A9, A11 RAa CAw RAb CA M aw0 aw1 aw2 aw3 b0 b1 b2 b3 Bank #0 Bank #1 Bank #2 Bank #3 Idle AP* AP* * AP is the internal precharge start timing Revision: A03

30 11.10 Auto Precharge (Burst Length = 4) CS RAS trc trc CAS tras tras WE BS0 BS1 trcd trcd A10 RAa RAb RAc A0-A9, A11 RAa CAw RAb CA RAc M aw0 aw1 aw2 aw3 b0 b1 b2 b3 Bank #0 Bank #1 AP* AP* Bank #2 Bank #3 Idle * AP is the internal precharge start timing Revision: A03

31 11.11 Auto Refresh Cycle CS trc trc RAS CAS WE BS0,1 A10 A0-A9, A11 M All Banks Prechage Auto Refresh Auto Refresh (Arbitrary Cycle) Revision: A03

32 11.12 Self Refresh Cycle CS RAS CAS WE BS0,1 A10 A0-A9, A11 M tsb tcks tcks Self Refresh Cycle txsr No Operation / Command Inhibit All Banks Precharge Self Refresh Entry Self Refresh Eit Arbitrary Cycle Revision: A03

33 11.13 Burst and Single (Burst Length = 4, CAS Latency = 3) CS RAS CAS WE trcd BS0 BS1 A10 RBa A0-A9, A11 RBa CBv CBw CB CBy CBz M av0 av1 av2 av3 aw0 a0 ay0 az0 az1 az2 az3 Q Q Q Q D D D Q Q Q Q Bank #0 Single Bank #1 Bank #2 Idle Bank # Revision: A03

34 11.14 Power down Mode CS RAS CAS WE BS A10 RAa RAa A0-A9, A11 RAa CAa RAa CA M tsb tsb tcks tcks tcks tcks a0 a1 a2 a3 NOP Precharge NOP Standby Power Down mode Precharge Standby Power Down mode Note: The Power Down Mode is entered by asserting "low". All Input/Output buffers (ecept buffers) are turned off in the Power Down mode. When goes high, command input must be No operation at net rising edge. Violating refresh requirements during power-down may result in a loss of data Revision: A03

35 11.15 Auto-precharge Timing ( Cycle) (1) CAS Latency=2 ( a ) burst length = 1 Command ( b ) burst length = 2 Command ( c ) burst length = 4 Command ( d ) burst length = 8 Command AP AP Act Q0 Q0 Q1 AP Act Q0 Act Q1 Q2 Q3 AP Q0 Q1 Q2 Q3 Q4 Q5 Q6 Q7 Act (2) CAS Latency=3 ( a ) burst length = 1 Command ( b ) burst length = 2 Command ( c ) burst length = 4 Command ( d ) burst length = 8 Command AP Act Q0 AP Act Q0 Q0 Q1 AP Act Q1 Q2 Q3 AP Act Q0 Q1 Q2 Q3 Q4 Q5 Q6 Q7 Note ) AP Act represents the with Auto precharge command. represents the start of internal precharging. represents the Bank Activate command. When the Auto precharge command is asserted, the period from Bank Activate command to the start of internal precgarging must be at least RAS(min). t Revision: A03

36 11.16 Auto-precharge Timing ( Cycle) (1) CAS Latency = 2 (a) burst length = 1 Command D0 twr AP Act (b) burst length = 2 Command D0 D1 twr AP Act (c) burst length = 4 Command D0 D1 D2 D3 twr AP Act (d) burst length = 8 Command D0 D1 D2 D3 D4 D5 D6 D7 twr AP Act (2) CAS Latency = 3 (a) burst length = 1 Command D0 twr AP Act (b) burst length = 2 Command D0 D1 twr AP Act (c) burst length = 4 Command D0 D1 D2 D3 twr AP Act (d) burst length = 8 Command D0 D1 D2 D3 D4 D5 D6 D7 twr AP Act Note ) AP Act represents the with Auto precharge command. represents the start of internal precharing. represents the Bank command. When the /auto precharge command is asserted,the period from Bank Activate command to the start of intermal precgarging must be at least tras (min) Revision: A03

37 11.17 Timing Chart of to Cycle In the case of Burst Length = 4 (1) CAS Latency= ( a ) Command M ( b ) Command D0 D1 D2 D3 M (2) CAS Latency=3 ( a ) Command M ( b ) Command D0 D1 D2 D3 D0 D1 D2 D3 M D0 D1 D2 D3 Note: The Output data must be masked by M to avoid I/O conflict Timing Chart of to Cycle In the case of Burst Length=4 (1) CAS Latency=2 ( a ) Command M D0 Q0 Q1 Q2 Q3 ( b ) Command M (2) CAS Latency=3 ( a ) Command M D0 D1 Q0 Q1 Q2 Q3 D0 Q0 Q1 Q2 Q3 ( b ) Command M D0 D1 Q0 Q1 Q2 Q Revision: A03

38 11.19 Timing Chart of Burst Stop Cycle (Burst Stop Command) (1) cycle ( a ) CAS latency =2 C ommand BST ( b )CAS latency = 3 C ommand Q0 Q1 Q2 Q3 Q4 BST Q0 Q1 Q2 Q3 Q4 (2) cycle C ommand BST Q0 Q1 Q2 Q3 Q4 Note: BST represents the Burst stop command Timing Chart of Burst Stop Cycle (Precharge Command) (1) cycle (a) CAS latency =2 Command (b) CAS latency =3 Command PRCG Q0 Q1 Q2 Q3 Q4 PRCG Q0 Q1 Q2 Q3 Q4 (2) cycle Command twr PRCG M Q0 Q1 Q2 Q3 Q Revision: A03

39 11.21 /M Input Timing ( Cycle) cycle No Eternal Internal M D1 D2 D3 D5 D6 M MASK MASK ( 1 ) cycle No Eternal Internal M D1 D2 D3 D5 D6 M MASK MASK ( 2 ) cycle No Eternal Internal M D1 D2 D3 D4 D5 D6 MASK ( 3 ) Revision: A03

40 11.22 /M Input Timing ( Cycle) cycle No Eternal Internal M Q1 Q2 Q3 Q4 Open Open Q6 ( 1 ) cycle No Eternal Internal M Q1 Q2 Q3 Q4 Open Q6 ( 2 ) cycle No Eternal Internal M Q1 Q2 Q3 Q4 Q5 Q6 ( 3 ) Revision: A03

41 12. PACKAGE SPECIFICATION Package Outline TFBGA 54 Ball (88 mm 2, ball pitch: 0.8mm, Ø =0.45mm) A1 INDEX A1 A 1 A1 INDEX A A A D1 SD e B C D E B C D E D F F G G H H J J Φb M C A B 0.08 M C SE E1 e ccc C C SEATING PLANE B 0.15 (4X) E SYMBOL DIMENSION (mm) DIMENSION (inch) MIN. NOM. MAX. MIN. NOM. MAX. A A b D D1 E BSC BSC E1 SE SD 6.40 BSC TYP TYP BSC TYP TYP. e 0.80 BSC BSC. ccc Ball Land Ball Opening Note: 1. Ball land : 0.5mm 2. Ball opening : 0.4mm 3. PCB Ball land suggested 0.4mm Revision: A03

42 13. REVISION HISTORY VERSION DATE PAGE DESCRIPTION A01 Dec. 23, 2011 All Initial formal datasheet A02 Oct. 15, Revise section Auto Refresh Cycle timing waveform diagram Added coplanarity ma. spec symbol ccc in section 12 package specification A03 Apr. 09, , 13~15 Removed -6A and -6K speed grade Mar.31, Remove important notice Revision: A03