Datasheet μPD46365084B μPD46365094B μPD46365184B μPD46365364B 36M-BIT QDRTM II SRAM 4-WORD BURST OPERATION R10DS0090EJ0400 Rev.4.00 Nov 09 2012 Description The μPD46365084B is a 4,194,304-word by 8-bit, the μPD46365094B is a 4,194,304-word by 9-bit, the μPD46365184B is a 2,097,152-word by 18-bit and the μPD46365364B is a 1,048,576-word by 36-bit synchronous quad data rate static RAM fabricated with advanced CMOS technology using full CMOS sixtransistor memory cell. The μPD46365084B, μPD46365094B, μPD46365184B and μPD46365364B integrate unique synchronous peripheral circuitry and a burst counter. All input registers controlled by an input clock pair (K and K#) are latched on the positive edge of K and K#. These products are suitable for application which require synchronous operation, high speed, low voltage, high density and wide bit configuration. These products are packaged in 165-pin PLASTIC BGA. Features • 1.8 ± 0.1 V power supply • 165-pin PLASTIC BGA (13 x 15) • HSTL interface • PLL circuitry for wide output data valid window and future frequency scaling • Separate independent read and write data ports with concurrent transactions • 100% bus utilization DDR READ and WRITE operation • Four-tick burst for reduced address frequency • Two input clocks (K and K#) for precise DDR timing at clock rising edges only • Two output clocks (C and C#) for precise flight time and clock skew matching-clock and data delivered together to receiving device • Internally self-timed write control • Clock-stop capability. Normal operation is restored in 20 μs after clock is resumed. • User programmable impedance output (35 to 70 Ω) • Fast clock cycle time : 3.3 ns (300 MHz) , 4.0 ns (250 MHz) • Simple control logic for easy depth expansion • JTAG 1149.1 compatible test access port R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 1 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Ordering Information Part No. μPD46365084BF1-E33-EQ1-A μPD46365084BF1-E40-EQ1-A μPD46365094BF1-E33-EQ1-A μPD46365094BF1-E40-EQ1-A μPD46365184BF1-E33-EQ1-A μPD46365184BF1-E40-EQ1-A μPD46365364BF1-E33-EQ1-A μPD46365364BF1-E40-EQ1-A μPD46365084BF1-E33Y-EQ1-A μPD46365084BF1-E40Y-EQ1-A μPD46365094BF1-E33Y-EQ1-A μPD46365094BF1-E40Y-EQ1-A μPD46365184BF1-E33Y-EQ1-A μPD46365184BF1-E40Y-EQ1-A μPD46365364BF1-E33Y-EQ1-A μPD46365364BF1-E40Y-EQ1-A μPD46365084BF1-E33-EQ1 μPD46365084BF1-E40-EQ1 μPD46365094BF1-E33-EQ1 μPD46365094BF1-E40-EQ1 μPD46365184BF1-E33-EQ1 μPD46365184BF1-E40-EQ1 μPD46365364BF1-E33-EQ1 μPD46365364BF1-E40-EQ1 μPD46365084BF1-E33Y-EQ1 μPD46365084BF1-E40Y-EQ1 μPD46365094BF1-E33Y-EQ1 μPD46365094BF1-E40Y-EQ1 μPD46365184BF1-E33Y-EQ1 μPD46365184BF1-E40Y-EQ1 μPD46365364BF1-E33Y-EQ1 μPD46365364BF1-E40Y-EQ1 R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Operating Ambient Temperature TA = 0 to 70°C Organization (word x bit) Cycle time Clock frequency Core Supply Voltage 4M x 8 3.3ns 300MHz 1.8 ± 0.1 V 4.0ns 250MHz 4M x 9 3.3ns 300MHz BGA 4.0ns 250MHz (13 x 15) 3.3ns 300MHz Lead-free 4.0ns 250MHz 2M x 18 1M x 36 4M x 8 4M x 9 2M x 18 1M x 36 3.3ns 300MHz 4.0ns 250MHz 3.3ns 300MHz 4.0ns 250MHz 3.3ns 300MHz 4.0ns 250MHz 3.3ns 300MHz 4.0ns 250MHz 3.3ns 300MHz Package 165-pin PLASTIC 1.8 ± 0.1 V TA = −40 to 85°C 1.8 ± 0.1 V TA = 0 to 70°C 4.0ns 250MHz 4M x 8 3.3ns 300MHz 4.0ns 250MHz 4M x 9 3.3ns 300MHz BGA 4.0ns 250MHz (13 x 15) Lead 2M x 18 1M x 36 4M x 8 4M x 9 2M x 18 1M x 36 3.3ns 300MHz 4.0ns 250MHz 3.3ns 300MHz 4.0ns 250MHz 3.3ns 300MHz 4.0ns 250MHz 3.3ns 300MHz 4.0ns 250MHz 3.3ns 300MHz 4.0ns 250MHz 3.3ns 300MHz 4.0ns 250MHz 165-pin PLASTIC 1.8 ± 0.1 V TA = −40 to 85°C Page 2 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Pin Arrangement 165-pin PLASTIC BGA (13 x 15) (Top View) [μPD46365084B] 4M x 8 1 2 3 4 5 6 7 8 9 10 11 A CQ# VSS/72M A W# NW1# K# NC/144M R# A A CQ B NC NC NC A NC/288M K NW0# A NC NC Q3 C NC NC NC VSS A NC A VSS NC NC D3 D NC D4 NC VSS VSS VSS VSS VSS NC NC NC E NC NC Q4 VDDQ VSS VSS VSS VDDQ NC D2 Q2 F NC NC NC VDDQ VDD VSS VDD VDDQ NC NC NC G NC D5 Q5 VDDQ VDD VSS VDD VDDQ NC NC NC H DLL# VREF VDDQ VDDQ VDD VSS VDD VDDQ VDDQ VREF ZQ J NC NC NC VDDQ VDD VSS VDD VDDQ NC Q1 D1 K NC NC NC VDDQ VDD VSS VDD VDDQ NC NC NC L NC Q6 D6 VDDQ VSS VSS VSS VDDQ NC NC Q0 M NC NC NC VSS VSS VSS VSS VSS NC NC D0 N NC D7 NC VSS A A A VSS NC NC NC P NC NC Q7 A A C A A NC NC NC R TDO TCK A A A C# A A A TMS TDI A D0 to D7 Q0 to Q7 R# W# NW0#, NW1# K, K# C, C# CQ, CQ# ZQ DLL# : Address inputs : Data inputs : Data outputs : Read input : Write input : Nibble Write data select : Input clock : Output clock : Echo clock : Output impedance matching : PLL disable TMS TDI TCK TDO VREF VDD VDDQ VSS NC NC/xxM : IEEE 1149.1 Test input : IEEE 1149.1 Test input : IEEE 1149.1 Clock input : IEEE 1149.1 Test output : HSTL input reference input : Power Supply : Power Supply : Ground : No connection : Expansion address for xxMb Remarks 1. ×××# indicates active LOW. 2. Refer to Package Dimensions for the index mark. 3. 2A, 7A and 5B are expansion addresses : 2A for 72Mb : 2A and 7A for 144Mb : 2A, 7A and 5B for 288Mb. 2A of this product can also be used as NC. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 3 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Pin Arrangement 165-pin PLASTIC BGA (13 x 15) (Top View) [μPD46365094B] 4M x 9 1 2 3 4 5 6 7 8 9 10 11 A CQ# VSS/72M A W# NC K# NC/144M R# A A CQ B NC NC NC A NC/288M K BW0# A NC NC Q4 C NC NC NC VSS A NC A VSS NC NC D4 D NC D5 NC VSS VSS VSS VSS VSS NC NC NC E NC NC Q5 VDDQ VSS VSS VSS VDDQ NC D3 Q3 F NC NC NC VDDQ VDD VSS VDD VDDQ NC NC NC G NC D6 Q6 VDDQ VDD VSS VDD VDDQ NC NC NC H DLL# VREF VDDQ VDDQ VDD VSS VDD VDDQ VDDQ VREF ZQ J NC NC NC VDDQ VDD VSS VDD VDDQ NC Q2 D2 K NC NC NC VDDQ VDD VSS VDD VDDQ NC NC NC L NC Q7 D7 VDDQ VSS VSS VSS VDDQ NC NC Q1 M NC NC NC VSS VSS VSS VSS VSS NC NC D1 N NC D8 NC VSS A A A VSS NC NC NC P NC NC Q8 A A C A A NC D0 Q0 R TDO TCK A A A C# A A A TMS TDI A D0 to D8 Q0 to Q8 R# W# BW0# K, K# C, C# CQ, CQ# ZQ DLL# : Address inputs : Data inputs : Data outputs : Read input : Write input : Byte Write data select : Input clock : Output clock : Echo clock : Output impedance matching : PLL disable TMS TDI TCK TDO VREF VDD VDDQ VSS NC NC/xxM : IEEE 1149.1 Test input : IEEE 1149.1 Test input : IEEE 1149.1 Clock input : IEEE 1149.1 Test output : HSTL input reference input : Power Supply : Power Supply : Ground : No connection : Expansion address for xxMb Remarks 1. ×××# indicates active LOW. 2. Refer to Package Dimensions for the index mark. 3. 2A, 7A and 5B are expansion addresses : 2A for 72Mb : 2A and 7A for 144Mb : 2A, 7A and 5B for 288Mb 2A of this product can also be used as NC. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 4 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Pin Arrangement 165-pin PLASTIC BGA (13 x 15) (Top View) [μPD46365184B] 2M x 18 1 2 3 4 5 6 7 8 9 10 11 A CQ# VSS/144M A W# BW1# K# NC/288M R# A VSS/72M CQ B NC Q9 D9 A NC K BW0# A NC NC Q8 C NC NC D10 VSS A NC A VSS NC Q7 D8 D NC D11 Q10 VSS VSS VSS VSS VSS NC NC D7 E NC NC Q11 VDDQ VSS VSS VSS VDDQ NC D6 Q6 F NC Q12 D12 VDDQ VDD VSS VDD VDDQ NC NC Q5 G NC D13 Q13 VDDQ VDD VSS VDD VDDQ NC NC D5 H DLL# VREF VDDQ VDDQ VDD VSS VDD VDDQ VDDQ VREF ZQ J NC NC D14 VDDQ VDD VSS VDD VDDQ NC Q4 D4 K NC NC Q14 VDDQ VDD VSS VDD VDDQ NC D3 Q3 L NC Q15 D15 VDDQ VSS VSS VSS VDDQ NC NC Q2 M NC NC D16 VSS VSS VSS VSS VSS NC Q1 D2 N NC D17 Q16 VSS A A A VSS NC NC D1 P NC NC Q17 A A C A A NC D0 Q0 R TDO TCK A A A C# A A A TMS TDI A D0 to D17 Q0 to Q17 R# W# BW0#, BW1# K, K# C, C# CQ, CQ# ZQ DLL# : Address inputs : Data inputs : Data outputs : Read input : Write input : Byte Write data select : Input clock : Output clock : Echo clock : Output impedance matching : PLL disable TMS TDI TCK TDO VREF VDD VDDQ VSS NC NC/xxM : IEEE 1149.1 Test input : IEEE 1149.1 Test input : IEEE 1149.1 Clock input : IEEE 1149.1 Test output : HSTL input reference input : Power Supply : Power Supply : Ground : No connection : Expansion address for xxMb Remarks 1. ×××# indicates active LOW. 2. Refer to Package Dimensions for the index mark. 3. 2A, 7A and 10A are expansion addresses : 10A for 72Mb : 10A and 2A for 144Mb : 10A, 2A and 7A for 288Mb 2A and 10A of this product can also be used as NC. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 5 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Pin Arrangement 165-pin PLASTIC BGA (13 x 15) (Top View) [μPD46365364B] 1M x 36 1 2 3 4 5 6 7 8 9 10 11 W# BW2# K# BW1# R# A VSS/144M CQ A CQ# B Q27 Q18 D18 A BW3# K BW0# A D17 Q17 Q8 C D27 Q28 D19 VSS A NC A VSS D16 Q7 D8 D D28 D20 Q19 VSS VSS VSS VSS VSS Q16 D15 D7 E Q29 D29 Q20 VDDQ VSS VSS VSS VDDQ Q15 D6 Q6 F Q30 Q21 D21 VDDQ VDD VSS VDD VDDQ D14 Q14 Q5 G D30 D22 Q22 VDDQ VDD VSS VDD VDDQ Q13 D13 D5 H DLL# VREF VDDQ VDDQ VDD VSS VDD VDDQ VDDQ VREF ZQ J D31 Q31 D23 VDDQ VDD VSS VDD VDDQ D12 Q4 D4 K Q32 D32 Q23 VDDQ VDD VSS VDD VDDQ Q12 D3 Q3 L Q33 Q24 D24 VDDQ VSS VSS VSS VDDQ D11 Q11 Q2 M D33 Q34 D25 VSS VSS VSS VSS VSS D10 Q1 D2 N D34 D26 Q25 VSS A A A VSS Q10 D9 D1 P Q35 D35 Q26 A A C A A Q9 D0 Q0 R TDO TCK A A A C# A A A TMS TDI VSS/288M NC/72M A D0 to D35 Q0 to Q35 R# W# BW0# to BW3# K, K# C, C# CQ, CQ# ZQ DLL# : Address inputs : Data inputs : Data outputs : Read input : Write input : Byte Write data select : Input clock : Output clock : Echo clock : Output impedance matching : PLL disable TMS TDI TCK TDO VREF VDD VDDQ VSS NC NC/xxM : IEEE 1149.1 Test input : IEEE 1149.1 Test input : IEEE 1149.1 Clock input : IEEE 1149.1 Test output : HSTL input reference input : Power Supply : Power Supply : Ground : No connection : Expansion address for xxMb Remarks 1. ×××# indicates active LOW. 2. Refer to Package Dimensions for the index mark. 3. 2A, 3A and 10A are expansion addresses : 3A for 72Mb : 3A and 10A for 144Mb : 3A, 10A and 2A for 288Mb 2A and 10A of this product can also be used as NC. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 6 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Pin Description (1/2) Symbol Type A Input D0 to Dxx Input Q0 to Qxx Output R# Input W# Input BWx# NWx# Input K, K# Input C, C# Input Description Synchronous Address Inputs: These inputs are registered and must meet the setup and hold times around the rising edge of K. All transactions operate on a burst of four words (two clock periods of bus activity). These inputs are ignored when device is deselected, i.e., NOP (R# = W# = HIGH). Synchronous Data Inputs: Input data must meet setup and hold times around the rising edges of K and K# during WRITE operations. See Pin Arrangement for ball site location of individual signals. x8 device uses D0 to D7. x9 device uses D0 to D8. x18 device uses D0 to D17. x36 device uses D0 to D35. Synchronous Data Outputs: Output data is synchronized to the respective C and C# or to K and K# rising edges if C and C# are tied HIGH. Data is output in synchronization with C and C# (or K and K#), depending on the R# command. See Pin Arrangement for ball site location of individual signals. x8 device uses Q0 to Q7. x9 device uses Q0 to Q8. x18 device uses Q0 to Q17. x36 device uses Q0 to Q35. Synchronous Read: When LOW this input causes the address inputs to be registered and a READ cycle to be initiated. This input must meet setup and hold times around the rising edge of K. If a READ command (R# = LOW) is input, an input of R# on the subsequent rising edge of K is ignored. Synchronous Write: When LOW this input causes the address inputs to be registered and a WRITE cycle to be initiated. This input must meet setup and hold times around the rising edge of K. If a WRITE command (W# = LOW) is input, an input of W# on the subsequent rising edge of K is ignored. Synchronous Byte Writes (Nibble Writes on x8): When LOW these inputs cause their respective byte or nibble to be registered and written during WRITE cycles. These signals must meet setup and hold times around the rising edges of K and K# for each of the two rising edges comprising the WRITE cycle. See Pin Arrangement for signal to data relationships. x8 device uses NW0#, NW1#. x9 device uses BW0#. x18 device uses BW0#, BW1#. x36 device uses BW0# to BW3#. See Byte Write Operation for relation between BWx#, NWx# and Dxx. Input Clock: This input clock pair registers address and control inputs on the rising edge of K, and registers data on the rising edge of K and the rising edge of K#. K# is ideally 180 degrees out of phase with K. All synchronous inputs must meet setup and hold times around the clock rising edges. Output Clock: This clock pair provides a user controlled means of tuning device output data. The rising edge of C# is used as the output timing reference for first and third output data. The rising edge of C is used as the output reference for second and fourth output data. Ideally, C# is 180 degrees out of phase with C. When use of K and K# as the reference instead of C and C#, then fixed C and C# to HIGH. Operation cannot be guaranteed unless C and C# are fixed to HIGH (i.e. toggle of C and C#). R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 7 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B (2/2) Symbol Type Description CQ, CQ# Output ZQ Input DLL# Input TMS TDI TCK Input TDO Output VREF − VDD Supply VDDQ Supply VSS Supply Power Supply: Ground NC − No Connect: These signals are not connected internally. Input Synchronous Echo Clock Outputs. The rising edges of these outputs are tightly matched to the synchronous data outputs and can be used as a data valid indication. These signals run freely and do not stop when Q tristates. If C and C# are stopped (if K and K# are stopped in the single clock mode), CQ and CQ# will also stop. Output Impedance Matching Input: This input is used to tune the device outputs to the system data bus impedance. Q, CQ and CQ# output impedance are set to 0.2 x RQ, where RQ is a resistor from this bump to ground. The output impedance can be minimized by directly connect ZQ to VDDQ. This pin cannot be connected directly to GND or left unconnected. The output impedance is adjusted every 20 μs upon power-up to account for drifts in supply voltage and temperature. After replacement for a resistor, the new output impedance is reset by implementing power-on sequence. PLL Disable: When debugging the system or board, the operation can be performed at a clock frequency slower than TKHKH (MAX.) without the PLL circuit being used, if DLL# = LOW. The AC/DC characteristics cannot be guaranteed. For normal operation, DLL# must be HIGH and it can be connected to VDDQ through a 10 kΩ or less resistor. IEEE 1149.1 Test Inputs: 1.8 V I/O level. These balls may be left Not Connected if the JTAG function is not used in the circuit. IEEE 1149.1 Clock Input: 1.8 V I/O level. This pin must be tied to VSS if the JTAG function is not used in the circuit. IEEE 1149.1 Test Output: 1.8 V I/O level. When providing any external voltage to TDO signal, it is recommended to pull up to VDD. HSTL Input Reference Voltage: Nominally VDDQ /2. Provides a reference voltage for the input buffers. Power Supply: 1.8 V nominal. See Recommended DC Operating Conditions and DC Characteristics for range. Power Supply: Isolated Output Buffer Supply. Nominally 1.5 V. 1.8 V is also permissible. See Recommended DC Operating Conditions and DC Characteristics for range. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 8 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Block Diagram [μPD46365084B] 20 ADDRESS R# ADDRESS W# 20 REGISTRY & LOGIC K W# MUX NW0# MEMORY ARRAY 16 OUTPUT BUFFER 16 32 OUTPUT SELECT & LOGIC OUTPUT REGISTER REGISTRY R# 2 x 32 SENSE AMPS D0 to D7 20 WRITE DRIVER DATA 8 WRITE REGISTER NW1# 8 16 16 Q0 to Q7 2 CQ, CQ# MUX K K K# K C, C# OR K, K# [μPD46365094B] 20 ADDRESS R# ADDRESS W# 20 REGISTRY & LOGIC K W# MUX BW0# MEMORY ARRAY 18 OUTPUT BUFFER 18 36 OUTPUT SELECT & LOGIC OUTPUT REGISTER REGISTRY 2 x 36 SENSE AMPS R# 20 WRITE DRIVER D0 to D8 WRITE REGISTER 9 DATA 9 18 18 Q0 to Q8 2 CQ, CQ# MUX K K# R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 K K C, C# OR K, K# Page 9 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B [μPD46365184B] 19 ADDRESS R# ADDRESS W# 19 REGISTRY & LOGIC K W# MUX BW0# 36 36 ARRAY 36 OUTPUT BUFFER 36 72 OUTPUT SELECT & LOGIC R# MEMORY 18 OUTPUT REGISTER REGISTRY 2 x 72 SENSE AMPS D0 to D17 19 WRITE DRIVER 18 DATA WRITE REGISTER BW1# Q0 to Q17 2 CQ, CQ# MUX K K K# K C, C# OR K, K# [μPD46365364B] 18 ADDRESS R# ADDRESS W# 18 REGISTRY & LOGIC K W# MUX ARRAY 72 OUTPUT BUFFER R# MEMORY 36 144 OUTPUT SELECT 72 2 x 144 SENSE AMPS & LOGIC 18 WRITE DRIVER REGISTRY WRITE REGISTER DATA 36 D0 to D35 72 72 OUTPUT REGISTER BW0# BW1# BW2# BW3# Q0 to Q35 2 CQ, CQ# MUX K K# R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 K K C, C# OR K, K# Page 10 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Power-On Sequence in QDR II SRAM QDR II SRAMs must be powered up and initialized in a predefined manner to prevent undefined operations. The following timing charts show the recommended power-on sequence. The following power-up supply voltage application is recommended: VSS, VDD, VDDQ, VREF, then VIN. VDD and VDDQ can be applied simultaneously, as long as VDDQ does not exceed VDD by more than 0.5 V during power-up. The following power-down supply voltage removal sequence is recommended: VIN, VREF, VDDQ, VDD, VSS. VDD and VDDQ can be removed simultaneously, as long as VDDQ does not exceed VDD by more than 0.5 V during power-down. Power-On Sequence Apply power and tie DLL# to HIGH. Apply VDDQ before VREF or at the same time as VREF. Provide stable clock for more than 20 μs to lock the PLL. Continuous min.4 NOP(R# = high) cycles are required after PLL lock up is done. PLL Constraints The PLL uses K clock as its synchronizing input and the input should have low phase jitter which is specified as TKC var. The PLL can cover 120 MHz as the lowest frequency. If the input clock is unstable and the PLL is enabled, then the PLL may lock onto an undesired clock frequency. Power-On Waveforms VDD/VDDQ VDD/VDDQ Stable (< ±0.1 V DC per 50 ns) DLL# Fix HIGH (or tied to VDDQ) Clock Unstable Clock 20 μs or more Stable Clock 4 Times NOP Normal Operation Start R# R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 11 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Truth Table Operation WRITE cycle CLK R# W# L→H H L D or Q Data in Load address, input write data on Input data DA(A+0) DA(A+1) DA(A+2) DA(A+3) consecutive K and K# rising edge Input clock K(t+1) ↑ K#(t+1) ↑ K(t+2) ↑ K#(t+2) ↑ READ cycle L→H L × Data out Load address, read data on Output data QA(A+0) QA(A+1) QA(A+2) QA(A+3) consecutive C and C# rising edge Output clock C#(t+1) ↑ C(t+2) ↑ C#(t+2) ↑ C(t+3) ↑ NOP (No operation) Clock stop L→H H H D = ×, Q = High-Z Stopped × × Previous state Remarks 1. H : HIGH, L : LOW, × : don’t care, ↑ : rising edge. 2. Data inputs are registered at K and K# rising edges. Data outputs are delivered at C and C# rising edges except if C and C# are HIGH then data outputs are delivered at K and K# rising edges. 3. All control inputs in the truth table must meet setup/hold times around the rising edge (LOW to HIGH) of K. All control inputs are registered during the rising edge of K. 4. This device contains circuitry that ensure the outputs to be in high impedance during power-up. 5. Refer to state diagram and timing diagrams for clarification. 6. It is recommended that K = K# = C = C# when clock is stopped. This is not essential but permits most rapid restart by overcoming transmission line charging symmetrically. 7. If R# was LOW to initiate the previous cycle, this signal becomes a don't care for this WRITE operation however it is strongly recommended that this signal is brought HIGH as shown in the truth table. 8. W# during write cycle and R# during read cycle were HIGH on previous K clock rising edge. Initiating consecutive READ or WRITE operations on consecutive K clock rising edges is not permitted. The device will ignore the second request. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 12 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Byte Write Operation [μPD46365084B] Operation K# NW0# NW1# L→H − 0 0 − L→H 0 0 L→H − 0 1 − L→H 0 1 Write D4 to D7 L→H − 1 0 − L→H 1 0 Write nothing L→H − 1 1 − L→H 1 1 Write D0 to D7 Write D0 to D3 K Remarks 1. H : HIGH, L : LOW, → : rising edge. 2. Assumes a WRITE cycle was initiated. NW0# and NW1# can be altered for any portion of the BURST WRITE operation provided that the setup and hold requirements are satisfied. [μPD46365094B] Operation Write D0 to D8 Write nothing K K# BW0# L→H − 0 − L→H 0 L→H − 1 − L→H 1 Remarks 1. H : HIGH, L : LOW, → : rising edge. 2. Assumes a WRITE cycle was initiated. BW0# can be altered for any portion of the BURST WRITE operation provided that the setup and hold requirements are satisfied. [μPD46365184B] Operation K# BW0# BW1# L→H − 0 0 − L→H 0 0 L→H − 0 1 − L→H 0 1 Write D9 to D17 L→H − 1 0 − L→H 1 0 Write nothing L→H − 1 1 − L→H 1 1 Write D0 to D17 Write D0 to D8 K Remarks 1. H : HIGH, L : LOW, → : rising edge. 2. Assumes a WRITE cycle was initiated. BW0# and BW1# can be altered for any portion of the BURST WRITE operation provided that the setup and hold requirements are satisfied. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 13 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B [μPD46365364B] Operation K# BW0# BW1# BW2# BW3# L→H − 0 0 0 0 − L→H 0 0 0 0 Write D0 to D8 L→H − 0 1 1 1 − L→H 0 1 1 1 Write D9 to D17 L→H − 1 0 1 1 − L→H 1 0 1 1 Write D18 to D26 L→H − 1 1 0 1 − L→H 1 1 0 1 Write D27 to D35 L→H − 1 1 1 0 − L→H 1 1 1 0 Write nothing L→H − 1 1 1 1 − L→H 1 1 1 1 Write D0 to D35 K Remarks 1. H : HIGH, L : LOW, → : rising edge. 2. Assumes a WRITE cycle was initiated. BW0# to BW3# can be altered for any portion of the BURST WRITE operation provided that the setup and hold requirements are satisfied. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 14 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Bus Cycle State Diagram LOAD NEW READ ADDRESS; R_Count = 0; R_Init = 1 LOAD NEW WRITE ADDRESS; W_Count = 0 Always W# = LOW & W_Count = 4 R# = LOW & R_Count = 4 WRITE DOUBLE; W_Count = W_Count+2 W# = LOW R_Init = 0 Always READ DOUBLE; R_Count = R_Count+2 R# = HIGH & R_Count = 4 W_Count = 2 Always R_Count = 2 Always R# = LOW INCREMENT WRITE ADDRESS BY TWO W# = HIGH & W_Count = 4 INCREMENT READ ADDRESS BY TWO R_Init = 0 R# = HIGH W# = HIGH WRITE PORT NOP Power UP Supply voltage provided Supply voltage provided READ PORT NOP R_Init = 0 Remarks 1. The address is concatenated with two additional internal LSBs to facilitate burst operation. The address order is always fixed as: xxx...xxx+0, xxx...xxx+1, xxx...xxx+2, xxx...xxx+3. Bus cycle is terminated at the end of this sequence (burst count = 4). 2. Read and write state machines can be active simultaneously. Read and write cannot be simultaneously initiated. Read takes precedence. 3. State machine control timing is controlled by K. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 15 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Electrical Characteristics Absolute Maximum Ratings Parameter Rating Unit VDD −0.5 to +2.5 V VDDQ −0.5 to VDD V Input voltage VIN −0.5 to VDD+0.5 (2.5 V MAX.) V Input / Output voltage VI/O −0.5 to VDDQ+0.5 (2.5 V MAX.) V Operating ambient temperature TA (E** series) 0 to 70 °C (E**Y series) -40 to 85 °C −55 to +125 °C Supply voltage Output supply voltage Storage temperature Symbol Conditions Tstg 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 to 70°C, TA = −40 to 85°C) Parameter MIN. TYP. MAX. Unit VDD 1.7 1.8 1.9 V Output supply voltage VDDQ 1.4 VDD V 1 Input HIGH voltage VIH (DC) VREF +0.1 VDDQ+0.3 V 1, 2 Input LOW voltage VIL (DC) −0.3 VREF −0.1 V 1, 2 Clock input voltage VIN −0.3 VDDQ+0.3 V 1, 2 Reference voltage VREF 0.68 0.95 V Supply voltage Symbol Conditions Note Notes 1. During normal operation, VDDQ must not exceed VDD. 2. Power-up: VIH ≤ VDDQ+0.3 V and VDD ≤ 1.7 V and VDDQ ≤ 1.4 V for t ≤ 200 ms Recommended AC Operating Conditions (TA = 0 to 70°C, TA = −40 to 85°C) Parameter Symbol Input HIGH voltage VIH (AC) Input LOW voltage VIL (AC) Conditions MIN. MAX. VREF +0.2 VREF −0.2 Unit Note V 1 V 1 Note 1. Overshoot: VIH (AC) ≤ VDD + 0.7 V (2.5 V MAX.) for t ≤ TKHKH/2 Undershoot: VIL (AC) ≥ −0.5 V for t ≤ TKHKH/2 Control input signals may not have pulse widths less than TKHKL (MIN.) or operate at cycle rates less than TKHKH (MIN.). R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 16 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B DC Characteristics 1 (TA = 0 to 70°C, VDD = 1.8 ± 0.1 V) Parameter Symbol Test condition MIN. MAX. x8 x9 Unit x18 x36 Input leakage current ILI −2 +2 μA I/O leakage current ILO −2 +2 μA Operating supply current IDD 520 520 580 740 mA (Read cycle / Write cycle) VIN ≤ VIL or VIN ≥ VIH, -E33 II/O = 0 mA,. Cycle = MAX. Standby supply current Note ISB1 (NOP) -E40 460 460 520 650 VIN ≤ VIL or VIN ≥ VIH, -E33 390 390 400 430 mA II/O = 0 mA,. Cycle = MAX. -E40 370 370 380 400 Inputs static Output HIGH voltage VOH(Low) VOH Output LOW voltage VOL(Low) VOL Notes 1. 2. 3. 4. |IOH| ≤ 0.1 mA Note1 IOL ≤ 0.1 mA Note2 VDDQ − 0.2 VDDQ V 3, 4 VDDQ/2−0.12 VDDQ/2+0.12 V 3, 4 VSS 0.2 V 3, 4 VDDQ/2−0.12 VDDQ/2+0.12 V 3, 4 Outputs are impedance-controlled. | IOH | = (VDDQ/2)/(RQ/5) ±15% for values of 175 Ω ≤ RQ ≤ 350 Ω. Outputs are impedance-controlled. IOL = (VDDQ/2)/(RQ/5) ±15% for values of 175 Ω ≤ RQ ≤ 350 Ω. AC load current is higher than the shown DC values. HSTL outputs meet JEDEC HSTL Class I standards. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 17 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B DC Characteristics 2 (TA = -40 to 85°C, VDD = 1.8 ± 0.1 V) Parameter Symbol Test condition MIN. MAX. x8 x9 Unit Note x18 x36 Input leakage current ILI −2 +2 μA I/O leakage current ILO −2 +2 μA Operating supply current IDD (Read cycle / Write cycle) Standby supply current VIN ≤ VIL or VIN ≥ VIH, -E33Y 640 640 710 870 mA Cycle = MAX. -E40Y 580 580 650 780 VIN ≤ VIL or VIN ≥ VIH, -E33Y 510 510 520 550 mA -E40Y 490 490 500 520 II/O = 0 mA,. ISB1 (NOP) II/O = 0 mA,. Cycle = MAX. Inputs static Output HIGH voltage VOH(Low) VOH Output LOW voltage VOL(Low) VOL Notes 1. 2. 3. 4. |IOH| ≤ 0.1 mA Note1 IOL ≤ 0.1 mA Note2 VDDQ − 0.2 VDDQ V 3, 4 VDDQ/2−0.12 VDDQ/2+0.12 V 3, 4 VSS 0.2 V 3, 4 VDDQ/2−0.12 VDDQ/2+0.12 V 3, 4 Outputs are impedance-controlled. | IOH | = (VDDQ/2)/(RQ/5) ±15% for values of 175 Ω ≤ RQ ≤ 350 Ω. Outputs are impedance-controlled. IOL = (VDDQ/2)/(RQ/5) ±15% for values of 175 Ω ≤ RQ ≤ 350 Ω. AC load current is higher than the shown DC values. HSTL outputs meet JEDEC HSTL Class I standards. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 18 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Capacitance (TA = 25°C, f = 1 MHz) Parameter Symbol Test conditions MIN. MAX. Unit Input capacitance (Address, Control) CIN VIN = 0 V 5 pF Input / Output capacitance CI/O VI/O = 0 V 7 pF Cclk Vclk = 0 V 6 pF (D, Q, CQ, CQ#) Clock Input capacitance Remark These parameters are periodically sampled and not 100% tested. Thermal Characteristics Parameter Thermal resistance Symbol θ ja Substrate 4-layer from junction to ambient air 8-layer Thermal characterization parameter Ψ jt 4-layer from junction to the top center of the package surface Thermal resistance 8-layer θ jc Airflow TYP. Unit 0 m/s 16.5 °C/W 1 m/s 13.2 °C/W 0 m/s 15.5 °C/W 1 m/s 12.6 °C/W 0 m/s 0.07 °C/W 1 m/s 0.13 °C/W 0 m/s 0.06 °C/W 1 m/s 0.12 °C/W 3.86 °C/W from junction to case R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 19 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B AC Characteristics (TA = 0 to 70°C, TA = −40 to 85°C,VDD = 1.8 ± 0.1 V) AC Test Conditions (VDD = 1.8 ± 0.1 V, VDDQ = 1.4 V to VDD) Input waveform (Rise / Fall time ≤ 0.3 ns) 1.25 V 0.75 V Test Points 0.75 V 0.25 V Output waveform Test Points VDDQ / 2 VDDQ / 2 Output load condition Figure 1. External load at test VDDQ / 2 0.75 V 50 Ω VREF ZO = 50 Ω SRAM 250 Ω ZQ R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 20 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Read and Write Cycle Parameter Clock Average Clock cycle time (K, K#, C, C#) Clock phase jitter (K, K#, C, C#) Clock HIGH time (K, K#, C, C#) Clock LOW time (K, K#, C, C#) Clock HIGH to Clock# HIGH (K → K#, C → C#) Clock# HIGH to Clock HIGH (K# → K, C# → C) Clock to data clock (K → C, K# → C#) PLL lock time (K, C) K static to PLL reset Symbol TKHKH -E33,-E33Y (300 MHz) MIN. MAX. 3.3 8.4 -E40,-E40Y (250 MHz) MIN. MAX. 4.0 0.2 Unit Note 8.4 ns 1 0.2 2 TKC var TKHKL TKLKH TKHK#H 1.32 1.32 1.49 1.6 1.6 1.8 ns ns ns ns TK#HKH 1.49 1.8 ns TKHCH 0 TKC lock TKC reset 20 30 20 30 μs ns 3 4 TCQHCQ#H 1.24 1.55 ns 5 TCQ#HCQH 1.24 1.55 ns 5 1.45 0 1.8 ns Output Times CQ HIGH to CQ# HIGH (CQ → CQ#) CQ# HIGH to CQ HIGH (CQ# → CQ) C, C# HIGH to output valid C, C# HIGH to output hold C, C# HIGH to echo clock valid C, C# HIGH to echo clock hold CQ, CQ# HIGH to output valid CQ, CQ# HIGH to output hold C HIGH to output High-Z C HIGH to output Low-Z Setup Times Address valid to K rising edge Control inputs (R#, W#) valid to K rising edge Data inputs and write data select inputs (BWx#, NWx#) valid to K, K# rising edge Hold Times K rising edge to address hold K rising edge to control inputs (R#, W#) hold K, K# rising edge to data inputs and write data select inputs (BWx#, NWx#) hold R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 TCHQV TCHQX TCHCQV TCHCQX TCQHQV TCQHQX TCHQZ TCHQX1 0.45 –0.45 –0.45 ns ns ns ns ns ns ns ns TAVKH TIVKH 0.4 0.4 0.5 0.5 ns ns 7 7 TDVKH 0.3 0.35 ns 7 TKHAX TKHIX 0.4 0.4 0.5 0.5 ns ns 7 7 TKHDX 0.3 0.35 ns 7 –0.45 0.45 –0.45 0.45 –0.45 0.45 –0.45 0.27 –0.27 0.3 –0.3 0.45 0.45 6 6 Page 21 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Notes 1. When debugging the system or board, these products can operate at a clock frequency slower than TKHKH (MAX.) without the PLL circuit being used, if DLL# = LOW. Read latency (RL) is changed to 1.0 clock cycle in this operation. The AC/DC characteristics cannot be guaranteed, however. 2. Clock phase jitter is the variance from clock rising edge to the next expected clock rising edge. TKC var (MAX.) indicates a peak-to-peak value. 3. VDD slew rate must be less than 0.1 V DC per 50 ns for PLL lock retention. PLL lock time begins once VDD and input clock are stable. It is recommended that the device is kept NOP (R# = W# = HIGH) during these cycles. 4. K input is monitored for this operation. See below for the timing. K TKC reset or K TKC reset 5. Guaranteed by design. 6. Echo clock is very tightly controlled to data valid / data hold. By design, there is a ± 0.1 ns variation from echo clock to data. The data sheet parameters reflect tester guardbands and test setup variations. 7. This is a synchronous device. All addresses, data and control lines must meet the specified setup and hold times for all latching clock edges. Remarks 1. This parameter is sampled. 2. Test conditions as specified with the output loading as shown in AC Test Conditions unless otherwise noted. 3. Control input signals may not be operated with pulse widths less than TKHKL (MIN.). 4. If C, C# are tied HIGH, K, K# become the references for C, C# timing parameters. 5. VDDQ is 1.5 V DC. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 22 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Read and Write Timing 1 2 WRITE READ WRITE READ NOP 3 4 5 NOP 6 7 K TKHKL TKLKH TKHKH TKHK#H TK#HKH K# R# TKHIX TIVKH TKHIX TIVKH W# A0 Address A2 A1 TDVKH TAVKH TKHAX Data in Data out Qx2 Qx3 TCHQX1 A3 TKHDX TDVKH TKHDX D10 D11 D12 D13 D30 D31 Q00 Q01 Q02 Q03 Q20 Q21 TCHQX D32 D33 Q22 Q23 TCQHQX TCHQX TCHQZ TCHQV TCQHQV TCHQV CQ TCHCQX TCHCQV TCQHCQ#H TCQ#HCQH CQ# TKHCH TCHCQX TCHCQV C TKHKL TKLKH TKHKH TKHK#H TK#HKH TKHCH C# Remarks 1. Q00 refers to output from address A0+0. Q01 refers to output from the next internal burst address following A0,i.e.,A0+1. 2. Outputs are disabled (high impedance) 3.5 clock cycles after the last READ (R# = LOW) is input in the sequences of [READ]-[NOP]-[NOP], [READ]-[WRITE]-[NOP] and [READ]-[NOP]-[WRITE]. 3. In this example, if address A2 = A1, data Q20 = D10, Q21 = D11, Q22 = D12 and Q23 = D13. Write data is forwarded immediately as read results. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 23 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Application Example SRAM#1 D Vt SRAM Controller A R# ZQ CQ# CQ Q R= 250 Ω D ZQ CQ# CQ Q A R# W# BWx# C/C# K/K# ... SRAM#4 W# BWx# C/C# K/K# R= 250 Ω R Data In Data Out R Address Vt R R# Vt W# BW# ... SRAM#1 CQ/CQ# SRAM#4 CQ/CQ# Vt R Vt R Source CLK/CLK# Return CLK/CLK# Vt R R = 50 Ω Vt = Vref Remark AC Characteristics are defined at the condition of SRAM outputs, CQ, CQ# and Q with termination. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 24 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B JTAG Specification These products support a limited set of JTAG functions as in IEEE standard 1149.1. Test Access Port (TAP) Pins Pin name Pin assignments Description TCK 2R TMS 10R TDI 11R Test Data Input. This is the input side of the serial registers placed between TDI and TDO. The register placed between TDI and TDO is determined by the state of the TAP controller state machine and the instruction that is currently loaded in the TAP instruction. TDO 1R Test Data Output. This is the output side of the serial registers placed between TDI and TDO. Output changes in response to the falling edge of TCK. Test Clock Input. All input are captured on the rising edge of TCK and all outputs propagate from the falling edge of TCK. Test Mode Select. This is the command input for the TAP controller state machine. Remark The device does not have TRST (TAP reset). The Test-Logic Reset state is entered while TMS is held HIGH for five rising edges of TCK. The TAP controller state is also reset on the SRAM POWER-UP. JTAG DC Characteristics (TA = 0 to 70°C, VDD = 1.8 ± 0.1 V, unless otherwise noted) Parameter Symbol Conditions MIN. MAX. Unit JTAG Input leakage current ILI 0 V ≤ VIN ≤ VDD −5.0 +5.0 μA JTAG I/O leakage current ILO 0 V ≤ VIN ≤ VDDQ, −5.0 +5.0 μA Outputs disabled JTAG input HIGH voltage VIH 1.3 VDD+0.3 V JTAG input LOW voltage VIL −0.3 +0.5 V JTAG output HIGH voltage JTAG output LOW voltage R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 VOH1 | IOHC | = 100 μA 1.6 V VOH2 | IOHT | = 2 mA 1.4 V VOL1 IOLC = 100 μA 0.2 V VOL2 IOLT = 2 mA 0.4 V Page 25 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B JTAG AC Test Conditions Input waveform (Rise / Fall time ≤ 1 ns) 1.8 V 0.9 V Test Points 0.9 V 0.9 V Test Points 0.9 V 0V Output waveform Output load Figure 2. External load at test VTT = 0.9 V 50 Ω ZO = 50 Ω TDO 20 pF R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 26 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B JTAG AC Characteristics (TA = 0 to 70°C) Parameter Symbol Conditions MIN. MAX. Unit Clock Clock cycle time tTHTH 50 ns Clock frequency fTF Clock HIGH time tTHTL 20 20 MHz ns Clock LOW time tTLTH 20 ns TCK LOW to TDO unknown tTLOX 0 TCK LOW to TDO valid tTLOV Output time ns 10 ns Setup time TMS setup time tMVTH 5 ns TDI valid to TCK HIGH tDVTH 5 ns tCS 5 ns TMS hold time tTHMX 5 ns TCK HIGH to TDI invalid tTHDX 5 ns tCH 5 ns Capture setup time Hold time Capture hold time JTAG Timing Diagram tTHTH TCK tMVTH tTHTL tTLTH TMS tTHMX tDVTH TDI tTHDX tTLOX tTLOV TDO R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 27 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Scan Register Definition (1) Register name Description Instruction register The instruction register holds the instructions that are executed by the TAP controller when it is moved into the run-test/idle or the various data register state. The register can be loaded when it is placed between the TDI and TDO pins. The instruction register is automatically preloaded with the IDCODE instruction at power-up whenever the controller is placed in test-logic-reset state. Bypass register The bypass register is a single bit register that can be placed between TDI and TDO. It allows serial test data to be passed through the RAMs TAP to another device in the scan chain with as little delay as possible. ID register The ID Register is a 32 bit register that is loaded with a device and vendor specific 32 bit code when the controller is put in capture-DR state with the IDCODE command loaded in the instruction register. The register is then placed between the TDI and TDO pins when the controller is moved into shift-DR state. Boundary register The boundary register, under the control of the TAP controller, is loaded with the contents of the RAMs I/O ring when the controller is in capture-DR state and then is placed between the TDI and TDO pins when the controller is moved to shift-DR state. Several TAP instructions can be used to activate the boundary register. The Scan Exit Order tables describe which device bump connects to each boundary register location. The first column defines the bit’s position in the boundary register. The second column is the name of the input or I/O at the bump and the third column is the bump number. Scan Register Definition (2) Register name Bit size Unit Instruction register 3 bit Bypass register 1 bit ID register 32 bit Boundary register 109 bit ID Register Definition Part number Organization ID [31:28] vendor revision no. ID [27:12] part no. ID [11:1] vendor ID no. ID [0] fix bit μPD46365084B 4M x 8 XXXX 0000 0000 0100 1101 00000010000 1 μPD46365094B 4M x 9 XXXX 0000 0000 0100 1110 00000010000 1 μPD46365184B 2M x 18 XXXX 0000 0000 0100 1111 00000010000 1 μPD46365364B 1M x 36 XXXX 0000 0000 0101 0000 00000010000 1 R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 28 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B SCAN Exit Order Bit no. Signal name x8 x9 x18 x36 Bump Bit Signal name ID no. x8 x9 x18 Bump Bit Signal name Bump x36 ID no. x8 x9 x18 x36 ID 1 C# 6R 37 NC NC NC D15 10D 73 NC NC NC Q28 2C 2 C 6P 38 NC NC NC Q15 9E 74 Q4 Q5 Q11 Q20 3E 3 A 6N 39 NC NC Q7 Q7 10C 75 D4 D5 D11 D20 2D 4 A 7P 40 NC NC D7 D7 11D 76 NC NC NC D29 2E 5 A 7N 41 NC NC NC D16 9C 77 NC NC NC Q29 1E 6 A 7R 42 NC NC NC Q16 9D 78 NC NC Q12 Q21 2F 7 A 8R 43 Q3 Q4 Q8 Q8 11B 79 NC NC D12 D21 3F 8 A 8P 44 D3 D4 D8 D8 11C 80 NC NC NC D30 1G 9 A 9R 45 NC NC NC D17 9B 81 NC NC NC Q30 1F NC NC NC Q17 10B 82 Q5 Q6 Q13 Q22 3G 11A 83 D5 D6 D13 D22 2G 10A 84 10 NC Q0 Q0 Q0 11P 46 11 NC D0 D0 D0 10P 47 12 NC NC NC D9 10N 48 13 NC NC NC Q9 9P 49 A 9A 85 NC NC NC D31 1J 14 NC NC Q1 Q1 10M 50 A 8B 86 NC NC NC Q31 2J 15 NC NC D1 D1 11N 51 A 7C 87 NC NC Q14 Q23 3K 16 NC NC NC D10 9M 52 NC 6C 88 NC NC D14 D23 3J 17 NC NC NC Q10 9N 53 R# 8A 89 NC NC NC D32 2K 18 Q0 Q1 Q2 Q2 11L 54 BW1# 7A 90 NC NC NC Q32 1K 19 D0 D1 D2 D2 11M 55 NW0# BW0# BW0# BW0# 7B 91 Q6 Q7 Q15 Q24 2L 20 NC NC NC D11 9L 56 K 6B 92 D6 D7 D15 D24 3L 21 NC NC NC Q11 10L 57 K# 6A 93 NC NC NC D33 1M 22 NC NC Q3 Q3 11K 58 NC NC BW3# 5B 94 NC NC NC Q33 1L 23 NC NC D3 D3 10K 59 NW1# NC BW1# BW2# 5A 95 NC NC Q16 Q25 3N 24 NC NC NC D12 9J 60 W# 4A 96 NC NC D16 D25 3M 25 NC NC NC Q12 9K 61 A 5C 97 NC NC NC D34 1N 26 Q1 Q2 Q4 Q4 10J 62 A 4B 98 NC NC NC Q34 2M 27 D1 D2 D4 D4 11J 63 3A 99 Q7 Q8 Q17 Q26 3P 11H 64 VSS 2A 100 D7 D8 D17 D26 2N CQ# 1A 101 NC NC NC D35 2P NC NC NC Q35 1P 28 ZQ CQ A NC A A VSS NC NC NC A A VSS NC DLL# 1H 29 NC NC NC D13 10G 65 30 NC NC NC Q13 9G 66 NC NC Q9 Q18 2B 102 31 NC NC Q5 Q5 11F 67 NC NC D9 D18 3B 103 A 3R 32 NC NC D5 D5 11G 68 NC NC NC D27 1C 104 A 4R 33 NC NC NC D14 9F 69 NC NC NC Q27 1B 105 A 4P 34 NC NC NC Q14 10F 70 NC NC Q10 Q19 3D 106 A 5P 35 Q2 Q3 Q6 Q6 11E 71 NC NC D10 D19 3C 107 A 5N 36 D2 D3 D6 D6 10E 72 NC NC NC D28 1D 108 A 5R 109 – Internal Remarks Bump ID 10A of bit no. 48 can also be used as NC if the product is x18 or x36. Bump ID 2A of bit no. 64 can also be used as NC. The register always indicates LOW, however. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 29 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B JTAG Instructions Instructions Description EXTEST The EXTEST instruction allows circuitry external to the component package to be tested. Boundary-scan register cells at output pins are used to apply test vectors, while those at input pins capture test results. Typically, the first test vector to be applied using the EXTEST instruction will be shifted into the boundary scan register using the PRELOAD instruction. Thus, during the update-IR state of EXTEST, the output drive is turned on and the PRELOAD data is driven onto the output pins. IDCODE The IDCODE instruction causes the ID ROM to be loaded into the ID register when the controller is in capture-DR mode and places the ID register between the TDI and TDO pins in shift-DR mode. The IDCODE instruction is the default instruction loaded in at power up and any time the controller is placed in the test-logic-reset state. BYPASS When the BYPASS instruction is loaded in the instruction register, the bypass register is placed between TDI and TDO. This occurs when the TAP controller is moved to the shiftDR state. This allows the board level scan path to be shortened to facilitate testing of other devices in the scan path. SAMPLE / PRELOAD SAMPLE / PRELOAD is a Standard 1149.1 mandatory public instruction. When the SAMPLE / PRELOAD instruction is loaded in the instruction register, moving the TAP controller into the capture-DR state loads the data in the RAMs input and Q pins into the boundary scan register. Because the RAM clock(s) are independent from the TAP clock (TCK) it is possible for the TAP to attempt to capture the I/O ring contents while the input buffers are in transition (i.e., in a metastable state). Although allowing the TAP to sample metastable input will not harm the device, repeatable results cannot be expected. RAM input signals must be stabilized for long enough to meet the TAPs input data capture setup plus hold time (tCS plus tCH). The RAMs clock inputs need not be paused for any other TAP operation except capturing the I/O ring contents into the boundary scan register. Moving the controller to shift-DR state then places the boundary scan register between the TDI and TDO pins. SAMPLE-Z If the SAMPLE-Z instruction is loaded in the instruction register, all RAM Q pins are forced to an inactive drive state (high impedance) and the boundary register is connected between TDI and TDO when the TAP controller is moved to the shift-DR state. JTAG Instruction Coding IR2 IR1 IR0 Instruction 0 0 0 EXTEST Note 0 0 1 IDCODE 0 1 0 SAMPLE-Z 1 0 1 1 RESERVED 2 1 0 0 SAMPLE / PRELOAD 1 0 1 RESERVED 2 1 1 0 RESERVED 2 1 1 1 BYPASS Notes 1. TRISTATE all Q pins and CAPTURE the pad values into a SERIAL SCAN LATCH. 2. Do not use this instruction code because the vendor uses it to evaluate this product. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 30 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Output Pin States of CQ, CQ# and Q Instructions Control-Register Status Output Pin Status CQ,CQ# Q 0 Update High-Z 1 Update Update 0 SRAM SRAM 1 SRAM SRAM SAMPLE-Z 0 High-Z High-Z 1 High-Z High-Z SAMPLE 0 SRAM SRAM 1 SRAM SRAM 0 SRAM SRAM 1 SRAM SRAM EXTEST IDCODE BYPASS Remark The output pin statuses during each instruction vary according to the Control-Register status (value of Boundary Scan Register, bit no. 109). Boundary Scan Register CAPTURE Register There are three statuses: Update : Contents of the “Update Register” are output to SRAM : Contents of the SRAM internal output “SRAM SRAM Output Update Register the output pin (QDR Pad). Update Output” are output to the output pin (QDR Pad). High-Z : The output pin (QDR Pad) becomes high impedance by controlling of the “High-Z JTAG QDR Pad SRAM ctrl”. High-Z The Control-Register status is set during Update-DR at the EXTEST or SAMPLE instruction. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 SRAM Output Driver High-Z JTAG ctrl Page 31 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Boundary Scan Register Status of Output Pins CQ, CQ# and Q Instructions SRAM Status Boundary Scan Register Status CQ,CQ# Q READ (Low-Z) Pad Pad NOP (High-Z) Pad Pad READ (Low-Z) – – NOP (High-Z) – – SAMPLE-Z READ (Low-Z) Pad Pad NOP (High-Z) Pad Pad SAMPLE READ (Low-Z) Internal Internal NOP (High-Z) Internal Pad READ (Low-Z) – – NOP (High-Z) – – EXTEST IDCODE BYPASS Remark The Boundary Scan Register statuses during execution each instruction vary according to the instruction code and SRAM operation mode. Note No definition No definition Boundary Scan Register CAPTURE Register There are two statuses: Internal Pad : Contents of the output pin (QDR Pad) are captured in the “CAPTURE Register” in the Boundary Scan Update Register Pad SRAM Output Register. Internal : Contents of the SRAM internal output “SRAM Output” are captured in the “CAPTURE Register” in the Boundary Scan Register. QDR Pad SRAM Output Driver High-Z JTAG ctrl R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 32 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B TAP Controller State Diagram 1 Test-Logic-Reset 0 1 0 1 1 Select-IR-Scan Select-DR-Scan Run-Test / Idle 0 0 1 1 Capture-IR Capture-DR 0 0 0 Shift-DR 0 Shift-IR 1 1 1 1 Exit1-DR Exit1-IR 0 0 0 Pause-DR 0 Pause-IR 1 1 0 0 Exit2-DR Exit2-IR 1 1 Update-DR 1 Update-IR 0 1 0 Disabling the Test Access Port It is possible to use this device without utilizing the TAP. To disable the TAP Controller without interfering with normal operation of the device, TCK must be tied to VSS to preclude mid level inputs. TDI and TMS may be left open but fix them to VDD via a resistor of about 1 kΩ when the TAP controller is not used. TDO should be left unconnected also when the TAP controller is not used. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 33 of 38 New Instruction μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Run-Test/Idle Update-IR Exit1-IR Shift-IR Exit2-IR IDCODE Pause-IR Exit1-IR Shift-IR R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Select-IR-Scan Run-Test/Idle Instruction Register state TDI Controller state TMS Test-Logic-Reset TDO Output Inactive Select-DR-Scan TCK Test Logic Operation (Instruction Scan) Capture-IR Page 34 of 38 IDCODE μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Test-Logic-Reset Select-IR-Scan Select-DR-Scan Run-Test/Idle Update-DR Exit1-DR Shift-DR Exit2-DR Instruction Pause-DR Exit1-DR Shift-DR Capture-DR R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Instruction Register state TDI Controller state TMS TCK Test Logic (Data Scan) Run-Test/Idle TDO Output Inactive Select-DR-Scan Page 35 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Package Dimensions 165-PIN PLASTIC BGA(13x15) ZD w S B E ZE B 11 10 9 8 7 6 5 4 3 2 1 A D R P N M L K J H G F E D C B A w S A INDEX MARK A y1 (UNIT:mm) A2 S S y e S b x A1 M S AB ITEM D DIMENSIONS 13.00±0.10 E 15.00±0.10 w 0.30 A 1.35±0.11 A1 0.37±0.05 A2 0.98 e 1.00 b +0.10 0.50 −0.05 x 0.10 y 0.15 y1 0.25 ZD 1.50 ZE 0.50 T165F1-100-EQ1 R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 36 of 38 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Recommended Soldering Condition Please consult with our sales offices for soldering conditions of these products. Types of Surface Mount Devices μPD46365084BF1-EQ1 : 165-pin PLASTIC BGA (13 x 15) μPD46365094BF1-EQ1 : 165-pin PLASTIC BGA (13 x 15) μPD46365184BF1-EQ1 : 165-pin PLASTIC BGA (13 x 15) μPD46365364BF1-EQ1 : 165-pin PLASTIC BGA (13 x 15) Quality Grade • A quality grade of the products is “Standard”. • Anti-radioactive design is not implemented in the products. • Semiconductor devices have the possibility of unexpected defects by affection of cosmic ray that reach to the ground and so forth. R10DS0090EJ0400 Rev.4.00 Nov 09, 2012 Page 37 of 38 Revision History Rev. Rev.1.00 Rev.2.00 Rev.3.00 Rev.4.00 Date ’11.05.19 ’11.11.07 ’12.07.13 ’12.11.09 μPD46365084B, μPD46365094B, μPD46365184B, μPD46365364B Page P11 ALL ALL Description Summary New Data Sheet Modified comments for Power on Sequence Addition : E**Y series Addition : -E33,-E33Y series, Lead series Deletion : -E50,-E50Y series All trademarks and registered trademarks are the property of their respective owners. C - 38 Notice 1. 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