A64S16161 Preliminary 2M X 16 Bit Low Voltage Super RAM Features ● Memory Cell : Dynamic memory( DRAM ) ● Refresh: Completely free 1 2 3 4 5 6 A LB# OE# A0 A1 A2 CE2 B DQ8 UB# A3 A4 CE1# DQ0 C DQ9 DQ10 A5 A6 DQ1 DQ2 D VSS DQ11 A17 A7 DQ3 VCC E VCC DQ12 NC A16 DQ4 VSS F DQ14 DQ13 A14 A15 DQ5 DQ6 G DQ15 A19 A12 A13 WE# DQ7 H A18 A8 A9 A10 A11 A20 ● Power Down: Control by CS2( No Data Retention ) ● Byte Control : Capable of single byte operation ● Power Consumption: 100μA( Standby Current ) ● Operating Temperature Range: -40’C~+85’C ● Composition:2,097,152 Word X 16 Bit ● Supply Power Voltage:2.70V to 3.30V ● Access Time: 70nS ● Access Time ( Page Access Read ): 30nS ● I/O Terminal :Input / Output Common 3-state output Pin Description Pin Name Description CS1# Chip select 1 ( Low Active ) CS2 Chip select 2 ( High Active ) WE# Write enable ( Low Active ) OE# Output enable ( Low Active ) A0 to A20 Address Input ( A0 to A2 : Page Address) IO0-7 Lower Byte Input / Output IO8-15 Upper Byte Input / Output LB# Lower Byte Control ( Low Active ) UB# Upper Byte Control ( Low Active ) VCC Power Supply VSS Ground ( 0V) Description A64S16161 is a virtually static RAM, which uses DRAM type memory cells, but it has refresh transparency, so that you need not to imply refresh operation. Furthermore the interface is completely compatible to a low power Asynchronous type SRAM, you can operate as same as the Asynchronous SRAM. A64S16161 is a 2,097,152 Words X 16 bit asynchronous random access memory on a monolithic CMOS chip with marvelous low power consumption technology. Its low power and also low noise makes it ideal for mobile applications. PRELIMINARY (December, 2003, Version 0.0) 1 AMIC Technology Corp. A64S16161 Block Diagram A0 A1 A2 A3 A4 A5 A6 A8 A10 A11 Address Buffer A9 Row Decoder 13 A7 8192 Memory Cell A12 A13 256X16 A14 A15 8 A16 Column 256 Column Gate A17 Decoder A18 A19 A20 ATD Control 16 Refresh Control CS1# CS1#,CS2 CS2 Control Input / Output Buffer WE# OE# LB# UB# WE#,OE# LB#,UB# Control I / O0 .............. PRELIMINARY (December, 2003, Version 0.0) 2 I / O15 AMIC Technology Corp. A64S16161 Functions Truth Table A0-20 CS1# CS2 WE# OE# LB# UB# I/O0~7 I/O8~15 Mode V L H H L L L Data-Out Data-Out Read V L H H L L H Data-Out High-Z Read V L H H L H L High-Z Data-Out Read V L H H X H H High-Z High-Z Output Disable V L H H H X X High-Z High-Z Output Disable V L H L H L L Data-In Data-In Write V L H L H L H Data-In High-Z Write V L H L H H L High-Z Data-In Write X H H X X X X High-Z High-Z Standby X X L X X X X High-Z High-Z Power Down*¹ V : Valid Address. X : High or Low .*1 No Data Retention Read Operation It is possible to control data width by LB# and UB# pins. (1)Reading data from lower byte Date can be read when the address is set while holding CS1#=L, CS2=H, OE #=L , WE #= H and LB #=L. (2)Reading data from upper byte Date can be read when the address is set while holding CS1#=L, CS2=H, OE #=L , WE #= H and UB #=L. (3)Reading date from both bytes Date can be read when the address is set while holding CS1#=L, CS2=H, OE #=L , WE #= H , LB #=L and UB #=L. (4)Page access read Date can be read by changing A0-A2 when A3-A20 is set while holding CS1#=L, CS2=H, WE #=H, OE #=L, LB #=L and UB #=L. Writing Operation (1) Writing data into lower byte ( WE # control ) Data can be written by adding L pulse into WE # when the address is set while holding CS1#=L, CS2=H, OE #=H, LB #=L and UB #=H. The data on lower byte are latched up into the memory cell during WE # =L and LB # =L. (2) Writing data into lower byte (LB # control) Data can be written by adding L pulse into LB # when the address is set while holding CS1#=L, CS2 =H, OE#=H, UB# =H and WE#=L. The data on lower byte are latched up into the memory cell during WE# =L and LB# = L. (3) Writing data into upper byte (WE # control) Data can be written by adding L pulse into WE # when the address is set while holding CS1 #=L, CS2 =H, OE #=H, LB # =H and UB #=L. The data on upper byte are latched up into the memory cell during WE # =L and UB # = L. PRELIMINARY (December, 2003, Version 0.0) 3 AMIC Technology Corp. A64S16161 (4) Writing data into upper byte (UB # control) Data can be written by adding L pulse into UB # when the address is set while holding CS1 #=L, CS2 =H, OE #=H, LB # =H and WE #=L. The data on upper byte are latched up into the memory cell during WE #=L and UB #=L. (5) Writing data into both byte ( WE # control) Data can be written by adding L pulse into WE # when the address is set while holding CS1 #=L, CS2=H, OE #=H, LB #=L and UB #=L. The data are latched up into the memory cell during WE #=L, LB #=L and UB #=L. (6) Writing data into both byte (LB #, UB # control) Data can be written by adding L pulse into LB# and UB# when the address is set while holding CS1#=L, CS2=H, OE #=H and WE #=L. The data are latched up into the memory cell during WE #=L, LB #=L and UB #=L Read or write with using both LB # and UB #, the timing edge of LB # and UB # must be same. While I/O pins are in the output state, the data that is opposite to the output data should not be given. Standby cycle When CS1# is H, the device will be in the standby cycle. In this case data I/O pins are Hi-Z and all input pins are inhibited. Power Down When CS2 is L, the device will be in the power down. In this case, an internal refresh stops and the data might be lost. ABSOLUTE MAXIMUM RATINGS (VSS=0V) Parameter Symbol Ratings Unit Supply voltage VCC -0.5 to 3.6 V Input voltage VI -0.5* to VCC+0.3 V Input / Output voltage V I/O -0.5* to VCC+0.3 V Input / Output voltage PD 0.5 W Operating temperature Topr -40 to 85 'C Storage temperature Tstg -65 to 150 `C * If pulse width is less than 5ns it is – 1.0V PRELIMINARY (December, 2003, Version 0.0) 4 AMIC Technology Corp. A64S16161 ELECTRICAL CHARACTERISTICS DC Recommended Operating Conditions (Ta=-40~85'C) Parameter Symbo1 Min Max Unit VCC 2.70 3.30 V VSS 0 0 V VIH VCC-0.3 VCC+0.3 V VIL -0.3* 0.3 V Supply voltage Input voltage * If pulse width is less than 5ns it is –1.0V DC ELECTRICAL CHARACTERISTICS DC Characteristics (Ta=-40~85’C) Parameter Symbol Condition Min Typ*¹ Max Unit Input leakage current ILI VI=0V to VCC -1 ﹣ 1 µA Output leakage current ILO LB# and UB#=H or CS1#=H or WE#=L -1 ﹣ 1 µA or OE#=H or CS2=L VI/O=0V to VCC High level output voltage VOH IOH=-0.5mA Vcc-0.3 ﹣ ﹣ V Low level output voltage VOL IOL=0.5mA ﹣ ﹣ 0.3 V Power Down Current IDDPD CS2≦0.2V ﹣ ﹣ 25 µA Standby Current IDDS VCC-0.2V≦CS1# ﹣ 60 100 µA Operating current IDDA1 I I/O=0mA, tcyc=70ns*² ﹣ 25 30 mA Operating current IDDA2 I I/O=0mA, tcyc=1uS*² ﹣ 3.0 3.5 mA Operating current IDDA3 I I/O=0mA, tcyc=70ns*³ - 20 30 mA *1:Typical values are measured at Ta=25’C and VCC =3.0V *2:Random access *3:Page access read Terminal Capacitance (Ta=25’C f=1MHz) Parameter Symbol Conditions Min Max Unit Input Capacitance CI VI=0V ﹣ 8 pF I/O Capacitance C I/O V I/O=0V ﹣ 10 pF Note:This parameter is measured by sampling , not of all products. PRELIMINARY (December, 2003, Version 0.0) 5 AMIC Technology Corp. A64S16161 AC Electrical Characteristics Read Cycle (Ta = - 30 ~ 85’C) Parameter Symbol Teat Conditions Min Max Unit Read cycle time tRC 1 70 32000 nS Page read cycle time tRCP 1 30 32000 nS Address access time tACC 1 - 70 nS Page address access time tACCP 1 - 30 nS CS1 # access time tACS 1 - 70 nS OE # access time tOE 1 - 35 nS LB # , UB # access time tAB 1 - 25 nS CS1# high pulse width tC1H 1 30 - nS Address set up to OE L # tASO 1 -5 - nS CS1 # output set time tCHZ 2 0 - nS CS1 # output floating time tCLZ 2 - 15 nS LB # , UB # output set time tBLZ 2 0 - nS LB # , UB # output floating time tBLZ 2 - 15 nS OE # output set time tOLZ 2 0 - nS OE # output floating time tOHZ 2 - 15 nS Output hold time tOH 1 5 - nS Parameter Symbol Test Conditions Min Max Unit Write cycle time tWC 1 70 32000 nS Chip select time tCW 1 60 - nS CS1# H pulse width tC1H Address enable time tAW 1 60 - nS Address set up time tAS 1 0 - nS Write pulse width tWP 1 40 - nS LB,UB select time tBW 1 60 - nS Address hold time tWR 1 0 - nS Data set up time tDW 1 30 - nS Data hold time tDH 1 0 - nS Write Cycle (Ta= - 40~85’C) PRELIMINARY (December, 2003, Version 0.0) 30 6 AMIC Technology Corp. A64S16161 Power Down Cycle(Ta= - 40~85'C) Parameter Symbol Test Conditions Min Max Unit CS1 # H set up time for Power Down entry tSSP 1 0 - nS CS1 # H hold time before Power Down exit tSHP 1 0 - nS CS2 L pulse width TC2LP 1 30 - nS CS1 # H hold time after Power Down exit tHPD 1 300 - µS Power Up Timing Requirement(Ta= - 40~85'C) Parameter Symbol Test Conditions Min Max Unit CS1 # CS2 set up time after Power Up tSHU 1 0 - nS Standby hold time after Power Up tHPU 1 300 - µS Data Retention Timing Requirement(Ta= - 40~85'C) Parameter Symbol Test Conditions Min Max Unit A3 to A20 hold time during active tBAH 1 - 32 nS CS1# L hold time for A3 to A20 fix tCSH 1 - 32 nS Either tBAH or tCSH required for data retention. Address Skew Timing Requirement(Ta= - 40~85'C) Parameter Symbol Test Conditions Min Max Unit Maximum address skew tSKEW 1 - 10 nS PRELIMINARY (December, 2003, Version 0.0) 7 AMIC Technology Corp. A64S16161 TEST CONDITION 1 Input pulse voltage level VCC – 0.3V / 0.3V Input ascend / descend time tr=tf=3nS Input output timing reference level 2.0V/0.8V Output load CL=50pF(Includes Jig capacity)+1TTL TEST CONDITION 2 Input pulse voltage level VCC – 0.3V / 0.3V Input ascend / descend time tr=tf=3nS Input output timing reference level ±100mV(The level change from stable voltage Output load CL=5pF(Includes Jig capacity)+1TTL I/O CL PRELIMINARY (December, 2003, Version 0.0) 8 AMIC Technology Corp. A64S16161 TIMING CHART Read Cycle tRC Address tACC tOH tACS CS1# tCHZ tAB LB#/UB# tASO tBHZ tOE OE# tOLZ tOHZ tBLZ Dout tCLZ CS2 and WE # must be H level for entire read cycle. Read Cycle ( Page Access [1] ) Address (A20-A3) No Change tRC tRCP tRCP Address (A2-A0) CS1# tCHZ tACS tACCP tACCP OE# tOH tOH tOH tCLZ Dout CS2 and WE # must be H level for entire read cycle. PRELIMINARY (December, 2003, Version 0.0) 9 AMIC Technology Corp. A64S16161 Read Cycle ( Page Access [2] ) Address (A20-A3) No Change tRC Address (A2-A0) tRCP tRCP tACS CS1# tASO tOE tCHZ tACCP tACCP OE# tOH tOH tOH tOLZ Dout CS2 and WE # must be H level for entire read cycle. Write Cycle ( WE # Control ) tWC Address tAW tCW CS1# tBW LB# / UB# tWR tAS tWP WE# tDW tDH Din CS2 and OE # must be H level for entire read cycle. PRELIMINARY (December, 2003, Version 0.0) 10 AMIC Technology Corp. A64S16161 Write Cycle ( LB # / UB # Control ) tWC Address tAW tCW CS1# tBW tWR tAS LB# / UB# tWP WE# tDW tDH Din CS2 and OE # must be H level for entire read cycle. Standby tC1H CS1# Active PRELIMINARY (December, 2003, Version 0.0) Standby 11 Active AMIC Technology Corp. A64S16161 Power Down Mode Entry / Exit CS1# tSHP tHPD tC2LP CS2 tSSP Power Up CS1# tSHU tHPU CS2 VCC VCC(min) Data Retention(1) tBAH Address (A20-A3) CS1# This applies for both read and write. PRELIMINARY (December, 2003, Version 0.0) 12 AMIC Technology Corp. A64S16161 Data Retention (2) tCSH Address (A20-A3) No Change CS1# This applies for both read and write. Address Skew(1) A0-20 tSKEW tRC / tWC CS1# tSKEW is from first address change to last address change Address Skew(2) A0-20 tRC / tWC tSKEW CS1# tSKEW is from first address change to last address change PRELIMINARY (December, 2003, Version 0.0) 13 AMIC Technology Corp. A64S16161 Address Skew(3) A0-20 tSKEW CS1# tSKEW is from first address change to stand-by Reference External Wiring Diagram Address Input Control Input / Output I / O0 WE# OE# CS1# CS2 BU# LB# I / O15 A0 A20 A64S16161 PRELIMINARY (December, 2003, Version 0.0) 14 AMIC Technology Corp. A64S16161 Ordering Information Part No. A64S0616G-70I Access Time (ns) Operating Current Max. (mA) Power Down Mode Standby Current Max. (µA) Package 70 30 25 48B Mini BGA Note: -I is for industrial operating temperature range PRELIMINARY (December, 2003, Version 0.0) 15 AMIC Technology Corp. A64S16161 48 Pins FBGA Package outline drawing -A0.10 6.00 PIN#1 -B- CAVITY 0.96 C C 8.00 C 0.08 0.25 -C- SOLDER BALL 0.10 0.1 C SEATING PLANE DETAIL : A 0.2 “A" 0.1 M M C A B C SECTION C-C 3.75 0.75 H B G 0.35 F 5.25 E A D C 1 B A “B" 2 DETAIL : B 1 2 3 4 5 6 PRELIMINARY (December, 2003, Version 0.0) 16 AMIC Technology Corp.