ELPIDA PD488588FF

DATA SHEET
288M bits Direct Rambus DRAM
for High Performance Solution
µPD488588FF-C80-40 (512K words × 18 bits × 32s banks)
Description
Features
The Direct Rambus DRAM (Direct RDRAM) is a
general purpose high-performance memory device
suitable for use in a broad range of applications
including computer memory, graphics, video, and any
other application where high bandwidth and low
latency are required.
The µPD488588FF is 288Mbits Direct Rambus DRAM
(RDRAM), organized as 16M words by 18 bits.
The use of Rambus Signaling Level (RSL) technology
permits 800MHz transfer rates while using
conventional system and board design technologies.
Direct RDRAM devices are capable of sustained data
transfers at 1.25ns per two bytes (10ns per sixteen
bytes).
The architecture of the Direct RDRAMs allows the
highest sustained bandwidth for multiple, simultaneous
randomly addressed memory transactions.
The separate control and data buses with independent
row and column control yield over 95% bus efficiency.
The Direct RDRAM’s four banks support up to four
simultaneous transactions.
System oriented features for mobile, graphics and
large memory systems include power management,
byte masking.
The µPD488588FF is offered in a CSP horizontal
package suitable for desktop as well as low-profile
add-in card and mobile applications. Direct RDRAMs
operate from a 2.5V supply.
• Highest sustained bandwidth per DRAM device
— 1.6 GB/s sustained data transfer rate
— Separate control and data buses for maximized
efficiency
— Separate row and column control buses for easy
scheduling and highest performance
— 32 banks: four transactions can take place
simultaneously at full bandwidth data rates
• Low latency features
— Write buffer to reduce read latency
— 3 precharge mechanisms for controller flexibility
— Interleaved transactions
• Advanced power management:
— Multiple low power states allows flexibility in power
consumption versus time to active state
— Power-down self-refresh
• Overdrive current mode
• Organization: 2K bytes pages and 32 banks, x 18
• Uses Rambus Signaling Level (RSL) for up to
800MHz operation
• Package : 80-ball FBGA (µ BGA) (17.16 × 10.2)
Application
The µPD488588FF is most appropriate for the
applications, such as consumer products demanding
vivid animations, processor memory for multimedia
and 3D graphics, network processing and storage
systems requiring scalability to accommodate future
designs.
Document No. E0251N20 (Ver. 2.0)
Date Published July 2002 (K) Japan
URL: http://www.elpida.com
Elpida Memory,Inc. 2002
Elpida Memory, Inc. is a joint venture DRAM company of NEC Corporation and Hitachi, Ltd.
µPD488588FF-C80-40
Ordering Information
Part number
Organization*
words × bits × Internal
Banks
Clock frequency
MHz (max.)
/RAS access
time (ns)
µ PD488588FF-C80-40-DH1
512K x 18 x 32s
800
40
Package
80-ball FBGA (µ BGA)
(17.16 × 10.2)
Note: The “32s” designation indicates that this RDRAM core is composed of 32 banks which use a “split” bank
architecture
2
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Pin Configuration
80-ball FBGA (µ BGA) (17.16 × 10.2)
Top View
10
9
8
7
6
5
4
3
2
1
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
A
O
B
O
C
VDD
GND
10
D
E
F
G
H
J
K
L
M
N
P
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
R
O
S
O
T
U
GND
VDD
9
8
GND
VDD
CMD
VDD
GND
GNDa
GNDa
VDD
7
VDD
DQA8
DQA7
DQA5
DQA3
DQA1
CTMN
CTM
4
GND
GND
DQA6
DQA4
DQA2
DQA0
CFM
3
VDD
GND
SCK
VDD
GND
VDD
GND
B
C
VDD
GND
VDD
VDD
GND
GND
VCMOS
VDD
GND
ROW2 ROW0
COL3
COL1
DQB1
DQB3
DQB5
DQB7
DQB8
VDD
CFMN
ROW1
COL4
COL2
COL0
DQB0
DQB2
DQB4
DQB6
GND
GND
VDDa
VREF
GND
VDD
GND
GND
VDD
SIO0
SIO1
GND
VDD
GND
VDD
S
T
GND
6
5
VCMOS GND
2
1
A
D
E
F
G
H
J
K
L
M
N
P
R
U
Note Some signals can be applied because this pin is not connected to the inside of the chip.
Data Sheet E0251N20 (Ver. 2.0)
3
µPD488588FF-C80-40
Pin Description
Signal
SIO0, SIO1
Input / Output
Type
#pins
Description
Note1
2
Serial input/output. Pins for reading from and writing to the control registers using
Input
CMOS Note1
1
Command input. Pins used in conjunction with SIO0 and SIO1 for reading from
Input
Note1
Input / Output CMOS
a serial access protocol. Also used for power management.
CMD
and writing to the control registers. Also used for power management.
SCK
CMOS
1
Serial clock input. Clock source used for reading from and writing to the control
registers.
VDD
18
Supply voltage for the RDRAM core and interface logic.
VDDa
1
Supply voltage for the RDRAM analog circuitry.
VCMOS
2
Supply voltage for CMOS input/output pins.
GND
22
Ground reference for RDRAM core and interface.
2
Ground reference for RDRAM analog circuitry.
9
Data byte A. Nine pins which carry a byte of read or write data between the
GNDa
DQA8..DQA0
Input / Output
RSL
Note2
RSL
Note2
RSL
Note2
Channel and the RDRAM.
CFM
Input
1
Clock from master. Interface clock used for receiving RSL signals from the
Channel. Positive polarity.
CFMN
Input
1
Clock from master. Interface clock used for receiving RSL signals from the
Channel. Negative polarity.
VREF
1
Logic threshold reference voltage for RSL signals.
Note2
1
Clock to master. Interface clock used for transmitting RSL signals to the Channel.
CTMN
Input
RSL
CTM
Input
RSL Note2
1
Clock to master. Interface clock used for transmitting RSL signals to the Channel.
ROW2..ROW0
Input
RSL Note2
3
Row access control. Three pins containing control and address information for
Input
Note2
Negative polarity.
Positive polarity.
row accesses.
COL4..COL0
RSL
5
Column access control. Five pins containing control and address information for
column accesses.
DQB8..DQB0
Input / Output
RSL Note2
9
Data byte B. Nine pins which carry a byte of read or write data between the
Channel and the RDRAM.
Total pin count per package
80
Notes 1. All CMOS signals are high-true ; a high voltage is a logic one and a low voltage is logic zero.
2. All RSL signals are low-true ; a low voltage is a logic one and a high voltage is logic zero.
4
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Block Diagram
RQ7..RQ5 or
ROW2..ROW0
DQB8..DQB0
CTM CTMN SCK, CMD SIO0, SIO1
3
9
2
RQ4..RQ0 or
COL4..COL0
CFM CFMN
2
DQA8..DQA0
5
9
RCLK
RCLK
1:8 Demux
1:8 Demux
TCLK
RCLK
Packet Decode
ROWR
ROWA
11
ROP
AV
5
5
DR
BR
Match
DM
Packet Decode
COLC
Control Registers
COLX
9
6
R
REFR
Power Modes
DEVID
Mux
XOP
M
5
5
DX
BX
5
COP
S
Match
Row Decode
5
5
DC
BC
Match
C
8
8
MB
MA
Write
Buffer
XOP Decode
PRER
ACT
COLM
7
PREX
Mux
Mux
Column Decode & Mask
Sense Amp
64x72
64x72
Bank 0
Bank 1
Bank 2
SAmp
13/14
SAmp
14/15
SAmp
17/18
SAmp
16/17
SAmp
16
SAmp
15
RCLK
TCLK
8:1 Mux
SAmp
29/30
SAmp SAmp
30/31
31
Bank 31
Data Sheet E0251N20 (Ver. 2.0)
9
SAmp SAmp
30/31
31
Bank 30
SAmp
29/30
Bank 29
•
•
•
8:1 Mux
•
•
•
9
9
SAmp
17/18
Bank 18
9
TCLK
Bank 17
SAmp
16/17
9
•
•
•
Bank 16
9
SAmp
16
9
72
1:8 Demux
Bank 15
Internal DQA Data Path
Write Buffer
Bank 14
SAmp
15
Write Buffer
Bank 13
•
•
•
SAmp
14/15
1:8 Demux
•
•
•
72
RCLK
•
•
•
SAmp
13/14
9
9
9
RD, WR
SAmp
1/2
SAmp
1/2
72
512x128x144
SAmp SAmp
0/1
0
72
SAmp SAmp
0/1
0
64x72
Internal DQB Data Path
PREC
DRAM Core
5
µPD488588FF-C80-40
CONTENTS
1. General Description.................................................................................................................................................8
2. Packet Format ........................................................................................................................................................10
3. Field Encoding Summary......................................................................................................................................12
4. DQ Packet Timing ..................................................................................................................................................14
5. COLM Packet to D Packet Mapping......................................................................................................................14
6. ROW-to-ROW Packet Interaction..........................................................................................................................16
7. ROW-to-COL Packet Interaction ...........................................................................................................................18
8. COL-to-COL Packet Interaction ............................................................................................................................19
9. COL-to-ROW Packet Interaction ...........................................................................................................................20
10. ROW-to-ROW Examples ......................................................................................................................................21
11. Row and Column Cycle Description ..................................................................................................................22
12. Precharge Mechanisms.......................................................................................................................................23
13. Read Transaction - Example...............................................................................................................................25
14. Write Transaction - Example...............................................................................................................................26
15. Write/Retire - Examples.......................................................................................................................................27
16. Interleaved Write - Example ................................................................................................................................29
17. Interleaved Read - Example ................................................................................................................................30
18. Interleaved RRWW - Example .............................................................................................................................31
19. Control Register Transactions............................................................................................................................32
20. Control Register Packets ....................................................................................................................................33
21. Initialization ..........................................................................................................................................................34
22. Control Register Summary..................................................................................................................................38
23. Power State Management....................................................................................................................................47
24. Refresh..................................................................................................................................................................52
25. Current and Temperature Control ......................................................................................................................54
26. Electrical Conditions ...........................................................................................................................................55
27. Timing Conditions ...............................................................................................................................................56
28. Electrical Characteristics ....................................................................................................................................58
29. Timing Characteristics ........................................................................................................................................58
30. RSL Clocking........................................................................................................................................................59
31. RSL - Receive Timing ..........................................................................................................................................60
32. RSL - Transmit Timing.........................................................................................................................................61
33. CMOS - Receive Timing.......................................................................................................................................62
34. CMOS - Transmit Timing .....................................................................................................................................64
35. RSL - Domain Crossing Window ........................................................................................................................65
36. Timing Parameters...............................................................................................................................................66
37. Absolute Maximum Ratings ................................................................................................................................67
6
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
38. IDD - Supply Current Profile .................................................................................................................................67
39. Capacitance and Inductance ..............................................................................................................................68
40. Interleaved Device Mode .....................................................................................................................................70
41. Glossary of Terms ...............................................................................................................................................74
42. Package Drawing .................................................................................................................................................76
43. Recommended Soldering Conditions ................................................................................................................77
Data Sheet E0251N20 (Ver. 2.0)
7
µPD488588FF-C80-40
1. General Description
The figure on page 5 is a block diagram of the µ PD488588. It consists of two major blocks : a “core” block built from
banks and sense amps similar to those found in other types of DRAM, and a Direct Rambus interface block which
permits an external controller to access this core at up to 1.6 GB/s.
Control Registers: The CMD, SCK, SIO0, and SIO1 pins appear in the upper center of the block diagram. They are
used to write and read a block of control registers. These registers supply the RDRAM configuration information to a
controller and they select the operating modes of the device. The nine bit REFR value is used for tracking the last
refreshed row. Most importantly, the five bits DEVID specifies the device address of the RDRAM on the Channel.
Clocking: The CTM and CTMN pins (Clock-To-Master) generate TCLK (Transmit Clock), the internal clock used to
transmit read data. The CFM and CFMN pins (Clock-From-Master) generate RCLK (Receive Clock), the internal
clock signal used to receive write data and to receive the ROW and COL pins.
DQA, DQB Pins: These 18 pins carry read (Q) and write (D) data across the Channel. They are multiplexed / demultiplexed from / to two 72-bit data paths (running at one-eighth the data frequency) inside the RDRAM.
Banks: The 32 Mbyte core of the RDRAM is divided into 32 one-Mbyte banks, each organized as 512 rows, with
each row containing 128 dualocts (2K bytes), and each dualoct containing 16 bytes. A dualoct is the smallest unit of
data that can be addressed.
Sense Amps: The RDRAM contains 34 sense amps. Each sense amp consists of 1,024 bytes of fast storage (512
for DQA and 512 for DQB) and can hold one-half of one row of one bank of the RDRAM. The sense amp may hold
any of the 512 half-rows of an associated bank. However, each sense amp is shared between two adjacent banks of
the RDRAM (except for numbers 0, 15, 30, and 31). This introduces the restriction that adjacent banks may not be
simultaneously accessed.
RQ Pins: These pins carry control and address information. They are broken into two groups. RQ7..RQ5 are also
called ROW2..ROW0, and are used primarily for controlling row accesses. RQ4..RQ0 are also called COL4..COL0,
and are used primarily for controlling column accesses.
ROW Pins: The principle use of these three pins is to manage the transfer of data between the banks and the sense
amps of the RDRAM. These pins are de-multiplexed into a 24-bit ROWA (row-activate) or ROWR (row-operation)
packet.
COL Pins: The principle use of these five pins is to manage the transfer of data between the DQA/DQB pins and the
sense amps of the RDRAM. These pins are de-multiplexed into a 23-bit COLC (column-operation) packet and either
a 17-bit COLM (mask) packet or a 17-bit COLX (extended-operation) packet.
ACT Command: An ACT (activate) command from an ROWA packet causes one of the 512 rows of the selected
bank to be loaded to its associated sense amps (two 512 byte sense amps for DQA and two for DQB).
PRER Command: A PRER (precharge) command from an ROWR packet causes the selected bank to release its
two associated sense amps, permitting a different row in that bank to be activated, or permitting adjacent banks to be
activated.
8
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
RD Command: The RD (read) command causes one of the 128 dualocts of one of the sense amps to be transmitted
on the DQA/DQB pins of the Channel.
WR Command: The WR (write) command causes a dualoct received from the DQA/DQB data pins of the Channel to
be loaded into the write buffer. There is also space in the write buffer for the BC bank address and C column
address information. The data in the write buffer is automatically retired (written with optional bytemask) to one of the
128 dualocts of one of the sense amps during a subsequent COP command. A retire can take place during a RD,
WR, or NOCOP to another device, or during a WR or NOCOP to the same device. The write buffer will not retire
during a RD to the same device. The write buffer reduces the delay needed for the internal DQA/DQB data path turnaround.
PREC Precharge: The PREC, RDA and WRA commands are similar to NOCOP, RD and WR, except that a precharge
operation is performed at the end of the column operation. These commands provide a second mechanism for
performing precharge.
PREX Precharge: After a RD command, or after a WR command with no byte masking (M=0), a COLX packet may
be used to specify an extended operation (XOP). The most important XOP command is PREX. This command
provides a third mechanism for performing precharge.
Data Sheet E0251N20 (Ver. 2.0)
9
µPD488588FF-C80-40
2. Packet Format
Figure 2-1 shows the formats of the ROWA and ROWR packets on the ROW pins. Table 2-1 describes the fields
which comprise these packets. DR4T and DR4F bits are encoded to contain both the DR4 device address bit and a
framing bit which allows the ROWA or ROWR packet to be recognized by the RDRAM.
The AV (ROWA/ROWR packet selection) bit distinguishes between the two packet types. Both the ROWA and
ROWR packet provide a five bit device address and a four bit bank address. An ROWA packet uses the remaining
bits to specify a nine bit row address, and the ROWR packet uses the remaining bits for an eleven bit opcode field.
Note the use of the “RsvX” notation to reserve bits for future address field extension.
Figure 2-1 also shows the formats of the COLC, COLM, and COLX packets on the COL pins. Table 2-2 describes
the fields which comprise these packets.
The COLC packet uses the S (Start) bit for framing. A COLM or COLX packet is aligned with this COLC packet, and
is also framed by the S bit.
The 23 bit COLC packet has a five bit device address, a four bit bank address, a six bit column address, and a four
bit opcode. The COLC packet specifies a read or write command, as well as some power management commands.
The remaining 17 bits are interpreted as a COLM (M=1) or COLX (M=0) packet. A COLM packet is used for a
COLC write command which needs bytemask control. The COLM packet is associated with the COLC packet from a
time tRTR earlier. An COLX packet may be used to specify an independent precharge command. It contains a five bit
device address, a four bit bank address, and a five bit opcode. The COLX packet may also be used to specify some
housekeeping and power management commands. The COLX packet is framed within a COLC packet but is not
otherwise associated with any other packet.
Table 2-1 Field Description for ROWA Packet and ROWR Packet
Field
Description
DR4T, DR4F
Bits for framing (recognizing) a ROWA or ROWR packet. Also encodes highest device address bit.
DR3..DR0
Device address for ROWA or ROWR packet.
BR4..BR0
Bank address for ROWA or ROWR packet. RsvB denotes bits ignored by the RDRAM.
AV
Selects between ROWA packet (AV=1) and ROWR packet (AV=0).
R8..R0
Row address for ROWA packet. RsvR denotes bits reserved for future row address extension.
ROP10..ROP0
Opcode field for ROWR packet. Specifies precharge, refresh, and power management functions.
Table 2-2 Field Description for COLC Packet, COLM Packet, and COLX Packet
Field
Description
S
Bit for framing (recognizing) a COLC packet, and indirectly for framing COLM and COLX packets.
DC4..DC0
Device address for COLC packet.
BC4..BC0
Bank address for COLC packet. RsvB denotes bits reserved for future extension (controller drivers 0's).
C6..C0
Column address for COLC packet.
COP3..COP0
Opcode field for COLC packet. Specifies read, write, precharge, and power management functions.
M
Selects between COLM packet (M=1) and COLX packet (M=0).
MA7..MA0
Bytemask write control bits. 1=write, 0=no-write. MA0 controls the earliest byte on DQA8..0.
MB7..MB0
Bytemask write control bits. 1=write, 0=no-write. MB0 controls the earliest byte on DQB8..0.
DX4..DX0
Device address for COLX packet.
BX4..BX0
Bank address for COLX packet. RsvB denotes bits reserved for future extension (controller drivers 0's).
XOP4..XOP0
Opcode field for COLX packet. Specifies precharge, IOL control, and power management functions.
10
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Figure 2-1 Packet Formats
T0
T1
T2
T3
T8
CTM/CFM
T9
T 10
T 11
CTM/CFM
ROW2
DR4T DR2 BR0 BR3 RsvR R8
R5
R2
ROW2
DR4T DR2 BR0 BR3 ROP10ROP8ROP5 ROP2
ROW1
DR4F DR1 BR1 BR4 RsvR R7
R4
R1
ROW1
DR4F DR1 BR1 BR4 ROP9ROP7ROP4ROP1
ROW0
DR3 DR0 BR2 RsvB AV=1
R3
R0
ROW0
DR3 DR0 BR2 RsvB AV=0 ROP6ROP3ROP0
R6
ROWA Packet
T0
T1
ROWR Packet
T2
T3
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12 T 13 T 14 T 15
CTM/CFM
CTM/CFM
S=1
C6
C4
C5
C3
COL4
DC4
COL3
DC3
COL2
DC2 COP1
RsvB BC2
C2
COL1
DC1 COP0
BC4 BC1
C1
COL0
DC0 COP2
COP3 BC3 BC0
C0
ROW2
..ROW0
ACT a0
COL4
..COL0
WR b1
PRER c0
t PACKET
MSK (b1)
PREX d0
DQA8..0
DQB8..0
COLC Packet
T8
T9
T 10
CTM/CFM
T 11
T 12
T 13
T 14
T 15
CTM/CFM
Note1
Note2
COL4
S=1 MA7 MA5 MA3 MA1
COL4
S=1 DX4 XOP4 RsvB BX1
COL3
M=1 MA6 MA4 MA2 MA0
COL3
M=0 DX3 XOP3 BX4 BX0
COL2
MB7 MB4 MB1
COL2
DX2 XOP2 BX3
COL1
MB6 MB3 MB0
COL1
DX1 XOP1 BX2
COL0
MB5 MB2
COL0
DX0 XOP0
COLM Packet
COLX Packet
Notes 1. The COLM is associated with a previous COLC, and is aligned with the present COLC, indicated
by the Start bit (S=1) position.
2. The COLX is aligned with the present COLC, indicates by the Start bit (S=1) position.
Data Sheet E0251N20 (Ver. 2.0)
11
µPD488588FF-C80-40
3. Field Encoding Summary
Table 3-1 shows how the six device address bits are decoded for the ROWA and ROWR packets. The DR4T and
DR4F encoding merges a fifth device bit with a framing bit. When neither bit is asserted, the device is not selected.
Note that a broadcast operation is indicated when both bits are set. Broadcast operation would typically be used for
refresh and power management commands. If the device is selected, the DM (DeviceMatch) signal is asserted and
an ACT or ROP command is performed.
Table 3-1 Device Field Encodings for ROWA Packet and ROWR Packet
DR4T
DR4F
Device Selection
Device Match signal (DM)
1
1
All devices (broadcast)
DM is set to 1
0
1
One device selected
DM is set to 1 if {DEVID4..DEVID0} == {0, DR3..DR0} else DM is set to 0
1
0
One device selected
DM is set to 1 if {DEVID4..DEVID0} == {1, DR3..DR0} else DM is set to 0
0
0
No packet present
DM is set to 0
Table 3-2 shows the encodings of the remaining fields of the ROWA and ROWR packets. An ROWA packet is
specified by asserting the AV bit. This causes the specified row of the specified bank of this device to be loaded into
the associated sense amps.
An ROWR packet is specified when AV is not asserted. An 11 bit opcode field encodes a command for one of the
banks of this device. The PRER command causes a bank and its two associated sense amps to precharge, so
another row or an adjacent bank may be activated.
The REFA (refresh-activate) command is similar to the ACT command, except the row address comes from an
internal register REFR, and REFR is incremented at the largest bank address. The REFP (refresh-precharge)
command is identical to a PRER command.
The NAPR, NAPRC, PDNR, ATTN, and RLXR commands are used for managing the power dissipation of the
RDRAM and are described in more detail in “23. Power State Management”. The TCEN and TCAL commands are
used to adjust the output driver slew rate and they are described in more detail in “25. Current and Temperature
Control”.
Table 3-2 ROWA Packet and ROWR Packet Field Encodings
DM
AV
Note1
ROP10..ROP0 Field
10 9
8
7
6
5
4
—
— —
0
—
— — — — —
1
1
Row address
1
0
1
1
0
0
0
1
0
0
0
0
1
1
1
0
1
0
1
0
1
0
0
1
0
x
x
0
0
0
0
1
1
0
x
x
0
0
0
1
0
1
0
x
x
0
0
0
1
1
1
0
x
x
x
x
x
x
1
0
x
x
x
x
x
1
0
0
0
0
0
0
x
3
Name
Command Description
—
No operation.
ACT
Activate row R8..R0 of bank BR4..BR0 of device and move device to
ATTN Note2.
2 :0
---
Note3
x
x
000 PRER
Precharge bank BR4..BR0 of this device.
0
0
x
000 REFA
Refresh (activate) row REFR8..REFR0 of bank BR3..BR0 of device.
Increment REFR if BR4..BR0=11111 (see Figure 24-1).
x
000 REFP
Precharge bank BR4..BR0 of this device after REFA (see Figure 24-1).
x
000 PDNR
Move this device into the powerdown (PDN) power state (see figure 23-3).
x
000 NAPR
Move this device into the nap (NAP) power state (see Figure 23-3).
x
000 NAPRC
Move this device into the nap (NAP) power state conditionally.
x
0
Note2
000 ATTN
Move this device into the attention (ATTN) power state (see Figure 23-1).
x
x
1
000 RLXR
Move this device into the standby (STBY) power state (see Figure 23-2).
0
0
x
001 TCAL
Temperature calibrate this device (see figure 25-2).
1
0
0
0
0
0
0
0
0
x
010 TCEN
Temperature calibrate/enable this device (see Figure 25-2).
1
0
0
0
0
0
0
0
0
0
000 NOROP
No operation.
Notes 1. The DM (Device Match signal) value is determined by the DR4T, DR4F, DR3..DR0 field of the ROWA and ROWR packets.
See Table 3-1.
2. The ATTN command does not cause a RLX-to-ATTN transition for a broadcast operation (DR4T/DR4F=1/1).
3. An “x” entry indicates which commands may be combined. For instance, the three commands PRER/NAPRC/RLXR may
be specified in one ROP value (011000111000).
12
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Table 3-3 shows the COP field encoding. The device must be in the ATTN power state in order to receive COLC
packets. The COLC packet is used primarily to specify RD (read) and WR (write) commands. Retire operations
(moving data from the write buffer to a sense amp) happen automatically. See Figure 15-1 for a more detailed
description.
The COLC packet can also specify a PREC command, which precharges a bank and its associated sense amps.
The RDA/WRA commands are equivalent to a combining RD/WR with a PREC. RLXC (relax) performs a power mode
transition. See 23. Power State Management.
Table 3-3 COLC Packet Field Encodings
S
DC4..DC0
(select device) Note1
COP3..0
Name
Command Description
0
----
-----
—
No operation.
1
/= (DEVID4..0)
-----
—
Retire write buffer of this device.
1
== (DEVID4..0)
x000 Note2
NOCOP
Retire write buffer of this device.
1
== (DEVID4..0)
x001
WR
Retire write buffer of this device, then write column C6..C0 of bank
BC4..BC0 to write buffer.
1
== (DEVID4..0)
x010
RSRV
Reserved, no operation.
1
== (DEVID4..0)
x011
RD
Read column C6..C0 of bank BC4..BC0 of this device.
1
== (DEVID4..0)
x100
PREC
Retire write buffer of this device, then precharge bank BC4..BC0 (see
Figure 12-2).
1
== (DEVID4..0)
x101
WRA
Same as WR, but precharge bank BC4..BC0 after write buffer (with new
data) is retired.
1
== (DEVID4..0)
x110
RSRV
Reserved, no operation.
1
== (DEVID4..0)
x111
RDA
Same as RD, but precharge bank BC4..BC0 afterward.
1
== (DEVID4..0)
1xxx
RLXC
Move this device into the standby (STBY) power state (see Figure 23-2).
Notes 1. “/=” means not equal, “==” means equal.
2. An “x” entry indicates which commands may be combined. For instance, the two commands WR/RLXC
may be specified in one COP value(1001).
Table 3-4 shows the COLM and COLX field encodings. The M bit is asserted to specify a COLM packet with two 8
bit bytemask fields MA and MB. If the M bit is not asserted, an COLX is specified. It has device and bank address
fields, and an opcode field. The primary use of the COLX packet is to permit an independent PREX (precharge)
command to be specified without consuming control bandwidth on the ROW pins. It is also used for the CAL
(calibrate) and SAM (sample) current control commands (see 25. Current and Temperature Control), and for the
RLXX power mode command (see 23. Power State Management).
Table 3-4 COLM Packet and COLX Packet Field Encodings
M
DX4..DX0
XOP4..0 Name
(select device)
Command Description
1
----
-
MSK
MB/MA bytemasks used by WR/WRA.
0
/= (DEVID4..0)
-
—
No operation.
NOXOP
No operation.
0
== (DEVID4..0)
00000
0
== (DEVID4..0)
1xxx0 Note PREX
Precharge bank BX4..BX0 of this device (see Figure 12-2).
0
== (DEVID4..0)
x10x0
CAL
Calibrate (drive) IOL current for this device (see Figure 25-1).
0
== (DEVID4..0)
x11x0
CAL / SAM Calibrate (drive) and Sample (update) IOL current for this device (see Figure 25-1).
0
== (DEVID4..0)
xxx10
RLXX
Move this device into the standby (STBY) power state (see Figure 23-2).
0
== (DEVID4..0)
xxxx1
RSRV
Reserved, no operation.
Note An “x” entry indicates which commands may be combined. For instance, the two commands PREX/RLXX
may be specified in one XOP value (10010).
Data Sheet E0251N20 (Ver. 2.0)
13
µPD488588FF-C80-40
4. DQ Packet Timing
Figure 4-1 shows the timing relationship of COLC packets with D and Q data packets. This document uses a
specific convention for measuring time intervals between packets: all packets on the ROW and COL pins (ROWA,
ROWR, COLC, COLM, COLX) use the trailing edge of the packet as a reference point, and all packets on the
DQA/DQB pins (D and Q) use the leading edge of the packet as a reference point.
An RD or RDA command will transmit a dualoct of read data Q a time tCAC later. This time includes one to five
cycles of round-trip propagation delay on the Channel. The tCAC parameter may be programmed to a one of a range
of values (7, 8, 9, 10, 11, or 12 tCYCLE). The value chosen depends upon the number of RDRAM devices on the
Channel and the RDRAM timing bin. See Figure 22-1(5/7) “TPARM Register” for more information.
A WR or WRA command will receive a dualoct of write data D a time tCWD later. This time does not need to include
the round-trip propagation time of the Channel since the COLC and D packets are traveling in the same direction.
When a Q packet follows a D packet (shown in the left half of the figure), a gap (tCAC-tCWD) will automatically appear
between them because the tCWD value is always less than the tCAC value. There will be no gap between the two COLC
packets with the WR and RD commands which schedule the D and Q packets.
When a D packet follows a Q packet (shown in the right half of the figure), no gap is needed between them because
the tCWD value is less than the tCAC value. However, a gap of tCAC - tCWD or greater must be inserted between the
COLC packets with the RD WR commands by the controller so the Q and D packets do not overlap.
Figure 4-1 Read (Q) and Write (D) Data Packet - Timing for tCAC = 7,8,9,10,11 or 12 tCYCLE
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
This gap on the DQA/DQB pins appears automatically
ROW2
..ROW0
t CAC -t CWD
t CAC -t CWD
t CWD
COL4
..COL0
This gap on the COL pins must be inserted by the controller
WR a1
•••
•••
RD b1
WR d1
t CWD
RD c1
Q (c1)
Q (b1)
DQA8..0
DQB8..0
D (d1)
D (a1)
t CAC
•••
•••
t CAC
5. COLM Packet to D Packet Mapping
Figure 5-1 shows a write operation initiated by a WR command in a COLC packet. If a subset of the 16 bytes of
write data are to be written, then a COLM packet is transmitted on the COL pins a time tRTR after the COLC packet
containing the WR command. The M bit of the COLM packet is set to indicate that it contains the MA and MB mask
fields. Note that this COLM packet is aligned with the COLC packet which causes the write buffer to be retired. See
Figure 15-1 for more details.
If all 16 bytes of the D data packet are to be written, then no further control information is required. The packet slot
that would have been used by the COLM packet (tRTR after the COLC packet) is available to be used as an COLX
packet. This could be used for a PREX precharge command or for a housekeeping command (this case is not
shown). The M bit is not asserted in an COLX packet and causes all 16 bytes of the previous WR to be written
unconditionally. Note that a RD command will never need a COLM packet, and will always be able to use the COLX
packet option (a read operation has no need for the byte-write-enable control bits).
The figure 5-1 also shows the mapping between the MA and MB fields of the COLM packet and bytes of the D
packet on the DQA and DQB pins. Each mask bit controls whether a byte of data is written (=1) or not written (=0).
14
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Figure 5-1 Mapping between COLM Packet and D Packet for WR Command
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
ROW2
..ROW0
ACT a0
PRER a2
ACT b0
t RTR
COL4
..COL0
WR a1
retire (a1)
MSK (a1)
t CWD
DQA8..0
DQB8..0
D (a1)
Transaction a: WR
a0 = {Da,Ba,Ra}
a1 = {Da,Ba,Ca1}
a3 = {Da,Ba}
COLM Packet
T 17
T 18
D Packet
T 19
T 20
CTM/CFM
T 19
T 20
T 21
T 22
CTM/CFM
COL4
MA7 MA5 MA3 MA1
DQB8
DB8
DB17 DB26 DB35 DB45 DB53 DB62 DB71
COL3
M=1 MA6 MA4 MA2 MA0
DQB7
DB7
DB16 DB25 DB34 DB44 DB52 DB61 DB70
COL2
MB7 MB4 MB1
•
•
•
COL1
MB6 MB3 MB0
DQB1
DB1
DB10 DB19 DB28 DB37 DB46 DB55 DB64
COL0
MB5 MB2
DQB0
DB0
DB9
DB18 DB27 DB36 DB45 DB54 DB63
MB0
MB1
MB2
DQA8
DA8
DA17 DA26 DA35 DA45 DA53 DA62 DA71
DQA7
DA7
DA16 DA25 DA34 DA44 DA52 DA61 DA70
DQA1
DA1
DA10 DA19 DA28 DA37 DA46 DA55 DA64
DQA0
DA0
DA9
DA18 DA27 DA36 DA45 DA54 DA63
MA0
MA1
MA2
MB3
MB4
MB5
MB6
MB7
Each bit of the MB7..MB0 field
controls writing (=1) or no writing
(=0) of the indicated DB bits when
the M bit of the COLM packet is one.
When M=1, the MA and MB
fields control writing of
individual data bytes.
When M=0, all data bytes are
written unconditionally.
•
•
•
Each bit of the MA7..MA0 field
controls writing (=1) or no writing
(=0) of the indicated DA bits when
the M bit of the COLM packet is one.
Data Sheet E0251N20 (Ver. 2.0)
MA3
MA4
MA5
MA6
MA7
15
µPD488588FF-C80-40
6. ROW-to-ROW Packet Interaction
Figure 6-1 shows two packets on the ROW pins separated by an interval tRRDELAY which depends upon the packet
contents. No other ROW packets are sent to banks {Ba, Ba+1, Ba-1} between packet “a” and packet “b” unless
noted otherwise.
Figure 6-1 ROW-to-ROW Packet Interaction - Timing
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T
CTM/CFM
t RRDELAY
ROW2
..ROW0
ROPa a0
ROPb b0
COL4
..COL0
DQA8..0
DQB8..0
Transaction a: ROPa
Transaction b: ROPb
a0 = {Da,Ba,Ra}
b0= {Db,Bb,Rb}
Table 6-1 summarizes the tRRDELAY values for all possible cases.
Cases RR1 through RR4 show two successive ACT commands. In case RR1, there is no restriction since the ACT
commands are to different devices. In case RR2, the tRR restriction applies to the same device with non-adjacent
banks. Cases RR3 and RR4 are illegal (as shown) since bank Ba needs to be precharged. If a PRER to Ba, Ba+1,
or Ba-1 is inserted, tRRDELAY is tRC (tRAS to the PRER command, and tRP to the next ACT).
Cases RR5 through RR8 show an ACT command followed by a PRER command. In cases RR5 and RR6, there are
no restrictions since the commands are to different devices or to non-adjacent banks of the same device. In cases
RR7 and RR8, the tRAS restriction means the activated bank must wait before it can be precharged.
Cases RR9 through RR12 show a PRER command followed by an ACT command. In cases RR9 and RR10, there
are essentially no restrictions since the commands are to different devices or to non-adjacent banks of the same
device. RR10a and RR10b depend upon whether a bracketed bank (Ba+-1) is precharged or activated. In cases
RR11 and RR12, the same and adjacent banks must all wait tRP for the sense amp and bank to precharge before
being activated.
Cases RR13 through RR16 summarize the combinations of two successive PRER commands. In case RR13 there
is no restriction since two devices are addressed. In RR14, tPP applies, since the same device is addressed. In
RR15 and RR16, the same bank or an adjacent bank may be given repeated PRER commands with only the tPP
restriction.
Two adjacent banks can’t be activate simultaneously. A precharge command to one bank will thus affect the state of
the adjacent banks (and sense amps). If bank Ba is activate and a PRER is directed to Ba, then bank Ba will be
precharged along with sense amps Ba-1/Ba and Ba/Ba+1. If bank Ba+1 is activate and a PRER is directed to Ba,
then bank Ba+1 will be precharged along with sense amps Ba/Ba+1 and Ba+1/Ba+2. If bank Ba-1 is activate and a
PRER is directed to Ba, then bank Ba-1 will be precharged along with sense amps Ba/Ba-1 and Ba-1/Ba-2.
A ROW packet may contain commands other than ACT or PRER. The REFA and REFP commands are equivalent
to ACT and PRER for interaction analysis purposes. The interaction rules of the NAPR, NAPRC, PDNR, RLXR,
ATTN, TCAL, and TCEN commands are discussed in later section (see Table 3-2 for cross-ref).
16
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Table 6-1 ROW-to-ROW Packet Interaction - Rules
Case #
ROPa Da
Ba
Ra
ROPb Db
Bb
Rb
tRRDELAY
Example
RR1
ACT
Da
Ba
Ra
ACT
/= Da
xxxx
x..x
tPACKET
Figure 10-2
RR2
ACT
Da
Ba
Ra
ACT
== Da /= {Ba, Ba+1, Ba-1}
x..x
tRR
Figure 10-2
RR3
ACT
Da
Ba
Ra
ACT
== Da == {Ba+1, Ba-1}
x..x
tRC - illegal unless PRER to Ba / Ba+1 / Ba-1
Figure 10-1
RR4
ACT
Da
Ba
Ra
ACT
== Da == {Ba}
x..x
tRC - illegal unless PRER to Ba / Ba+1 / Ba-1
Figure 10-1
RR5
ACT
Da
Ba
Ra
PRER /= Da
xxxx
x..x
tPACKET
Figure 10-2
RR6
ACT
Da
Ba
Ra
PRER == Da /= {Ba, Ba+1, Ba-1}
x..x
tPACKET
Figure 10-2
RR7
ACT
Da
Ba
Ra
PRER == Da == {Ba+1, Ba-1}
x..x
tRAS
Figure 10-1
RR8
ACT
Da
Ba
Ra
PRER == Da == {Ba}
x..x
tRAS
Figure 13-1
RR9
PRER Da
Ba
Ra
ACT
/= Da
x..x
tPACKET
Figure 10-3
RR10
PRER Da
Ba
Ra
ACT
== Da /= {Ba, Ba+-1, Ba+-2}
x..x
tPACKET
Figure 10-3
RR10a
PRER Da
Ba
Ra
ACT
== Da == {Ba+2}
x..x
tPACKET/tRP if Ba+1 is precharged/activated.
xxxx
RR10b
PRER Da
Ba
Ra
ACT
== Da == {Ba-2}
x..x
tPACKET/tRP if Ba-1 is precharged/activated.
RR11
PRER Da
Ba
Ra
ACT
== Da == {Ba+1, Ba-1}
x..x
tRP
== Da == {Ba}
RR12
PRER Da
Ba
Ra
ACT
RR13
PRER Da
Ba
Ra
PRER /= Da
RR14
PRER Da
Ba
Ra
PRER == Da /= {Ba, Ba+1, Ba-1}
RR15
PRER Da
Ba
Ra
PRER == Da == {Ba+1, Ba-1}
RR16
PRER Da
Ba
Ra
PRER == Da == {Ba}
x..x
xxxx
Figure 10-1
x..x
tRP
Figure 10-1
x..x
tPACKET
Figure 10-3
x..x
tPP
Figure 10-3
x..x
tPP
Figure 10-3
tPP
Figure 10-3
Data Sheet E0251N20 (Ver. 2.0)
17
µPD488588FF-C80-40
7. ROW-to-COL Packet Interaction
Figure 7-1 shows two packets on the ROW and COL pins. They must be separated by an interval tRCDELAY which
depends upon the packet contents.
Figure 7-1 ROW-to-COL Packet Interaction- Timing
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T
CTM/CFM
t RCDELAY
ROW2
..ROW0
ROPa a0
COL4
..COL0
COPb b1
DQA8..0
DQB8..0
Transaction a: ROPa
Transaction b: COPb
a0 = {Da,Ba,Ra}
b1= {Db,Bb,Cb1}
Table 7-1 summarizes the tRCDELAY values for all possible cases. Note that if the COL packet is earlier than the
ROW packet, it is considered a COL-to-ROW packet interaction.
Cases RC1 through RC5 summarize the rules when the ROW packet has an ACT command. Figure 13-1 and
Figure 14-1 show examples of RC5 - an activation followed by a read or write. RC4 is an illegal situation, since a
read or write of a precharged banks is being attempted (remember that for a bank to be activated, adjacent banks
must be precharged). In cases RC1, RC2, and RC3, there is no interaction of the ROW and COL packets.
Cases RC6 through RC8 summarize the rules when the ROW packet has a PRER command. There is either no
interaction (RC6 through RC9) or an illegal situation with a read or write of a precharged bank (RC9).
The COL pins can also schedule a precharge operation with a RDA, WRA, or PREC command in a COLC packet or
a PREX command in a COLX packet. The constraints of these precharge operations may be converted to equivalent
PRER command constraints using the rules summarized in Figure 12-2.
Table 7-1 ROW-to-COL Packet Interaction - Rules
Case # ROPa Da
Ba
Ra
COPb
RC1
ACT
Da
Ba
Ra
NOCOP, RD, retire /= Da
Db
Bb
Cb1
tRCDELAY Example
xxxx
x..x
0
RC2
ACT
Da
Ba
Ra
NOCOP
RC3
ACT
Da
Ba
Ra
RD, retire
== Da
xxxx
x..x
0
== Da
/= {Ba, Ba+1, Ba-1}
x..x
RC4
ACT
Da
Ba
Ra
0
RD, retire
== Da
== {Ba+1, Ba-1}
x..x
RC5
ACT
Da
Ba
Illegal
Ra
RD, retire
== Da
== {Ba}
x..x
tRCD
RC6
PRER Da
RC7
PRER Da
Ba
Ra
NOCOP, RD, retire /= Da
xxxx
x..x
0
Ba
Ra
NOCOP
xxxx
x..x
0
== Da
RC8
PRER Da
Ba
Ra
RD, retire
== Da
/= {Ba, Ba+1, Ba-1}
x..x
0
RC9
PRER Da
Ba
Ra
RD, retire
== Da
== {Ba+1, Ba-1}
x..x
Illegal
18
Data Sheet E0251N20 (Ver. 2.0)
Figure 13-1
µPD488588FF-C80-40
8. COL-to-COL Packet Interaction
Figure 8-1 COL-to-COL Packet Interaction- Timing
Figure 8-1 shows three arbitrary packets on the
COL pins. Packets “b” and “c” must be separated by
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T
an interval tCCDELAY which depends upon the
CTM/CFM
command and address values in all three packets.
Table 8-1 summarizes the tCCDELAY values for all
possible cases.
Cases CC1 through CC5 summarize the rules for
every situation other than the case when COPb is a
WR command and COPc is a RD command. In
ROW2
..ROW0
t CCDELAY
COL4
..COL0
COPa a1 COPb b1
COPc c1
CC3, when a RD command is followed by a WR
DQA8..0
DQB8..0
command, a gap of tCAC - tCWD must be inserted
between the two COL packets. See Figure 4-1 for
Transaction a: COPa
Transaction b: COPb
Transaction c: COPc
more explanation of why this gap is needed. For
cases CC1, CC2, CC4, and CC5, there is no
a1 = {Da,Ba,Ca1}
b1 = {Db,Bb,Cb1}
c1 = {Dc,Bc,Cc1}
restriction (tCCDELAY is tCC).
In cases CC6 through CC10, COPb is a WR command and COPc is a RD command. The tCCDELAY value needed
between these two packets depends upon the command and address in the packet with COPa. In particular, in case
CC6 when there is WR-WR-RD command sequence directed to the same device, a gap will be needed between the
packets with COPb and COPc. The gap will need a COLC packet with a NOCOP command directed to any device in
order to force an automatic retire to take place. Figure 15-2 (right) provides a more detailed explanation of this case.
In case CC10, there is a RD-WR-RD sequence directed to the same device. If a prior write to the same device is
unretired when COPa is issued, then a gap will be needed between the packets with COPb and COPc as in case
CC6. The gap will need a COLC packet with a NOCOP command directed to any device in order to force an
automatic retire to take place.
Cases CC7, CC8, and CC9 have no restriction (tCCDELAY is tCC).
For the purposes of analyzing COL-to-ROW interactions, the PREC, WRA, and RDA commands of the COLC
packet are equivalent to the NOCOP, WR, and RD commands. These commands also cause a precharge operation
PREC to take place. This precharge may be converted to an equivalent PRER command on the ROW pins using the
rules summarized in Figure 12-2.
Table 8-1 COL-to-COL Packet Interaction - Rules
Case #
COPa
Da
Ba
Ca1 COPb
Db
Bb
Cb1 COPc
Dc
Bc
Cc1 tCCDELAY
CC1
xxxx
xxxxx
x..x
x..x
NOCOP Db
Bb
Cb1 xxxx
xxxxx
x..x
x..x
tCC
CC2
xxxx
xxxxx
x..x
x..x
RD, WR Db
Bb
Cb1 NOCOP xxxxx
x..x
x..x
tCC
CC3
xxxx
xxxxx
x..x
x..x
RD
Db
Bb
Cb1 WR
xxxxx
x..x
x..x
tCC + tCAC - tCWD
CC4
xxxx
xxxxx
x..x
x..x
RD
Db
Bb
Cb1 RD
xxxxx
x..x
x..x
tCC
Figure 13-1
CC5
xxxx
xxxxx
x..x
x..x
WR
Db
Bb
Cb1 WR
xxxxx
x..x
x..x
tCC
Figure 14-1
Figure 15-1
CC6
WR
== Db
x
x..x
WR
Db
Bb
Cb1 RD
== Db
x..x
x..x
tRTR
CC7
WR
== Db
x
x..x
WR
Db
Bb
Cb1 RD
/= Db
x..x
x..x
tCC
CC8
WR
/= Db
x
x..x
WR
Db
Bb
Cb1 RD
== Db
x..x
x..x
tCC
CC9
NOCOP == Db
x
x..x
WR
Db
Bb
Cb1 RD
== Db
x..x
x..x
tCC
CC10
RD
x
x..x
WR
Db
Bb
Cb1 RD
== Db
x..x
x..x
tCC
== Db
Data Sheet E0251N20 (Ver. 2.0)
Example
Figure 4-1
19
µPD488588FF-C80-40
9. COL-to-ROW Packet Interaction
Figure 9-1 COL-to-ROW Packet Interaction- Timing
Figure 9-1 shows arbitrary packets on the COL
and ROW pins. They must be separated by an
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T
interval tCRDELAY which depends upon the
CTM/CFM
command and address values in the packets.
t CRDELAY
Table 9-1 summarizes the tCRDELAY value for all
ROW2
..ROW0
possible cases.
Cases CR1, CR2, CR3, and CR9 show no
interaction between the COL and ROW packets,
either because one of the commands is a NOP or
COL4
..COL0
ROPb b0
COPa a1
because the packets are directed to different
DQA8..0
DQB8..0
devices or to non-adjacent banks.
Case CR4 is illegal because an already-activated
Transaction a: COPa
Transaction b: ROPb
bank is to be re-activated without being
a1= {Da,Ba,Ca1}
b0= {Db,Bb,Rb}
precharged. Case CR5 is illegal because an
adjacent bank can’t be activated or precharged
until bank Ba is precharged first.
In case CR6, the COLC packet contains a RD command, and the ROW packet contains a PRER command for the
same bank. The tRDP parameter specifies the required spacing.
Likewise, in case CR7, the COLC packet causes an automatic retire to take place, and the ROW packet contains a
PRER command for the same bank. The tRTP parameter specifies the required spacing.
Case CR8 is labeled “Hazardous” because a WR command should always be followed by an automatic retire before
a precharge is scheduled. Figure 15-3 shows an example of what can happen when the retire is not able to happen
before the precharge.
For the purposes of analyzing COL-to-ROW interactions, the PREC, WRA, and RDA commands of the COLC
packet are equivalent to the NOCOP, WR, and RD commands. These commands also cause a precharge operation
to take place. This precharge may converted to an equivalent PRER command on the ROW pins using the rules
summarized in Figure 12-2.
A ROW packet may contain commands other than ACT or PRER. The REFA and REFP commands are equivalent
to ACT and PRER for interaction analysis purposes. The interaction rules of the NAPR, PDNR, and RLXR
commands are discussed in a later section.
Table 9-1 COL-to-ROW Packet Interaction - Rules
Case #
COPa
Da
Ba
Ca1
ROPb
Db
Bb
Rb
tCRDELAY Example
CR1
NOCOP
Da
Ba
Ca1
x..x
xxxxx
xxxxx
x..x
0
CR2
RD/WR
Da
Ba
Ca1
x..x
/= Da
xxxxx
x..x
0
CR3
RD/WR
Da
Ba
Ca1
x..x
== Da
/= {Ba, Ba+1, Ba-1} x..x
0
CR4
RD/WR
Da
Ba
Ca1
ACT
== Da
== {Ba}
x..x
Illegal
CR5
RD/WR
Da
Ba
Ca1
ACT
== Da
== {Ba+1, Ba-1}
x..x
Illegal
CR6
RD
Da
Ba
Ca1
PRER
== Da
== {Ba, Ba+1, Ba-1} x..x
tRDP
Figure 13-1
CR7
retire Note 1
Da
Ba
Ca1
PRER
== Da
== {Ba, Ba+1, Ba-1} x..x
tRTP
Figure 14-1
CR8
WR Note 2
Da
Ba
Ca1
PRER
== Da
== {Ba, Ba+1, Ba-1} x..x
0
Figure 15-3
CR9
xxxx
Da
Ba
Ca1
NOROP xxxxx
xxxxx
0
x..x
Notes 1. This is any command which permits the write buffer of device Da to retire (see Table 3-3). “Ba” is the bank
address in the write buffer.
2. This situation is hazardous because the write buffer will be left unretired while the targeted bank is
precharged. See Figure 15-3.
20
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
10. ROW-to-ROW Examples
Figure 10-1 shows examples of some of the ROW-to-ROW packet spacings from Table 6-1. A complete sequence
of activate and precharge commands is directed to a bank. The RR8 and RR12 rules apply to this sequence. In
addition to satisfying the tRAS and tRP timing parameters, the separation between ACT commands to the same bank
must also satisfy the tRC timing parameter (RR4).
When a bank is activated, it is necessary for adjacent banks to remain precharged. As a result, the adjacent banks
will also satisfy parallel timing constraints; in the example, the RR11 and RR3 rules are analogous to the RR12 and
RR4 rules.
Figure 10-1 Row Packet Example
Same Device
Same Device
Same Device
Same Device
Same Device
Adjacent Bank
Adjacent Bank
Same Bank
Adjacent Bank
Same Bank
a0 = {Da,Ba,Ra}
a1 = {Da,Ba+1}
b0 = {Da,Ba+1,Rb}
b0 = {Da,Ba,Rb}
b0 = {Da,Ba+1,Rb}
b0 = {Da,Ba,Rb}
RR7
RR3
RR4
RR11
RR12
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
ROW2
..ROW0
ACT a0
PRER a1
ACT b0
COL4
..COL0
t RAS
t RP
DQA8..0
DQB8..0
t RC
Figure 10-2 shows examples of the ACT-to-ACT (RR1, RR2) and ACT-to-PRER (RR5, RR6) command spacings
from Table 6-1. In general, the commands in ROW packets may be spaced an interval tPACKET apart unless they are
directed to the same or adjacent banks or unless they are a similar command type (both PRER or both ACT)
directed to the same device.
Figure 10-2 Row Packet Example
Different Device
Same Device
Different Device
Same Device
Any Bank
Non-adjacent Bank
Any Bank
Non-adjacent Bank
RR1
RR2
RR5
RR6
a0 = {Da,Ba,Ra}
b0 = {Db,Bb,Rb}
c0 = {Da,Bc,Rc}
b0 = {Db,Bb,Rb}
c0 = {Da,Bc,Rc}
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
ROW2
..ROW0
ACT a0
t PACKET
ACT b0
ACT a0
ACT c0
t RR
ACT a0
t PACKET
PRER b0
ACT a0
PRER c0
t PACKET
COL4
..COL0
DQA8..0
DQB8..0
Data Sheet E0251N20 (Ver. 2.0)
21
µPD488588FF-C80-40
Figure 10-3 shows examples of the PRER-to-PRER (RR13, RR14) and PRER-to-ACT (RR9, RR10) command
spacings from Table 6-1. The RR15 and RR16 cases (PRER-to-PRER to same or adjacent banks) are not shown,
but are similar to RR14. In general, the commands in ROW packets may be spaced an interval tPACKET apart unless
they are directed to the same or adjacent banks or unless they are a similar command type (both PRER or both ACT)
directed to the same device.
Figure 10-3 Row Packet Example
Different Device
Same Device
Same Device
Same Device
Different Device
Same Device
Any Bank
Non-adjacent Bank
Ajacent Bank
Same Bank
Any Bank
Non-adjacent Bank
RR13
RR14
RR15
RR16
RR9
RR10
a0 = {Da,Ba,Ra}
b0 = {Db,Bb,Rb}
c0 = {Da,Bc,Rc}
c0 = {Da,Ba,Rc}
c0 = {Da,Ba+1Rc}
b0 = {Db,Bb,Rb}
c0 = {Da,Bc,Rc}
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
ROW2
..ROW0
PRER a0 PRER b0
PRER a0
t PACKET
PRER c0
t PP
PRER a0
t PACKET
ACT b0
PRER a0
ACT c0
t PACKET
COL4
..COL0
DQA8..0
DQB8..0
11. Row and Column Cycle Description
Activate: A row cycle begins with the activate (ACT) operation. The activation process is destructive; the act of
sensing the value of a bit in a bank’s storage cell transfers the bit to the sense amp, but leaves the original bit in the
storage cell with an incorrect value.
Restore: Because the activation process is destructive, a hidden operation called restore is automatically performed.
The restore operation rewrites the bits in the sense amp back into the storage cells of the activated row of the bank.
Read/Write: While the restore operation takes place, the sense amp may be read (RD) and written (WR) using
column operations. If new data is written into the sense amp, it is automatically forwarded to the storage cells of the
bank so the data in the activated row and the data in the sense amp remain identical.
Precharge: When both the restore operation and the column operations are completed, the sense amp and bank are
precharged (PRE). This leaves them in the proper state to begin another activate operation.
Intervals: The activate operation requires the interval tRCD,MIN to complete. The hidden restore operation requires the
interval tRAS,MIN - tRCD,MIN to complete. Column read and write operations are also performed during the tRAS,MIN tRCD,MIN interval (if more than about four column operations are performed, this interval must be increased). The
precharge operation requires the interval tRP,MIN to complete.
Adjacent Banks: An RDRAM with a “s” designation (512K x 18 x 32s) indicates it contains “split banks”. This means
the sense amps are shared between two adjacent banks. The only exception is that sense amp 0, 15, 30, and 31 are
not shared. When a row in a bank is activated, the two adjacent sense amps are connected to (associated with) that
bank and are not available for use by the two adjacent banks. These two adjacent banks must remain precharged
while the selected bank goes through its activate, restore, read/write, and precharge operations.
For example (referring to the block diagram), if bank 5 is accessed, sense amp 4/5 and sense amp 5/6 will both be
loaded with one of the 512 rows (with 1,024 bytes loaded into each sense amp from the 2K byte row – 512 bytes to
the DQA side and 512 bytes to the DQB side). While this row from bank 5 is being accessed, no rows may be
accessed in banks 4 or 6 because of the sense amp sharing.
22
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
12. Precharge Mechanisms
Figure 12-1 shows an example of precharge with the ROWR packet mechanism. The PRER command must occur
a time tRAS after the ACT command, and a time tRP before the next ACT command. This timing will serve as a
baseline against which the other precharge mechanisms can be compared.
Figure 12-1 Precharge via PRER Command in ROWR Packet
a0 = {Da,Ba,Ra}
a5 = {Da,Ba}
b0 = {Da,Ba,Rb}
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
ROW2
..ROW0
ACT a0
PRER a5
ACT b0
COL4
..COL0
t RAS
t RP
DQA8..0
DQB8..0
t RC
Figure 12-2 (top) shows an example of precharge with a RDA command. A bank is activated with an ROWA packet
on the ROW pins. Then, a series of four dualocts are read with RD commands in COLC packets on the COL pins.
The fourth of these commands is a RDA, which causes the bank to automatically precharge when the final read has
finished. The timing of this automatic precharge is equivalent to a PRER command in an ROWR packet on the ROW
pins that is offset a time tOFFP from the COLC packet with the RDA command. The RDA command should be treated
as a RD command in a COLC packet as well as a simultaneous (but offset) PRER command in an ROWR packet
when analyzing interactions with other packets.
Figure 12-2 (middle) shows an example of precharge with a WRA command. As in the RDA example, a bank is
activated with an ROWA packet on the ROW pins. Then, two dualocts are written with WR commands in COLC
packets on the COL pins. The second of these commands is a WRA, which causes the bank to automatically
precharge when the final write has been retired. The timing of this automatic precharge is equivalent to a PRER
command in an ROWR packet on the ROW pins that is offset a time tOFFP from the COLC packet that causes the
automatic retire. The WRA command should be treated as a WR command in a COLC packet as well as a
simultaneous (but offset) PRER command in an ROWR packet when analyzing interactions with other packets. Note
that the automatic retire is triggered by a COLC packet a time tRTR after the COLC packet with the WR command
unless the second COLC contains a RD command to the same device. This is described in more detail in Figure 151.
Figure 12-2 (bottom) shows an example of precharge with a PREX command in an COLX packet. A bank is
activated with an ROWA packet on the ROW pins. Then, a series of four dualocts are read with RD commands in
COLC packets on the COL pins. The fourth of these COLC packets includes an COLX packet with a PREX
command. This causes the bank to precharge with timing equivalent to a PRER command in an ROWR packet on
the ROW pins that is offset a time tOFFP from the COLX packet with the PREX command.
Data Sheet E0251N20 (Ver. 2.0)
23
µPD488588FF-C80-40
Figure 12-2 Offsets for Alternate Precharge Mechanisms
COLC Packet: RDA Precharge Offset
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
The RDA precharge is equivalent to a PRER command here
ROW2
..ROW0
ACT a0
ACT b0
PRER a5
t OFFP
COL4
..COL0
RD a1
RD a2
RD a3
DQA8..0
DQB8..0
RDA a4
Q (a1)
Transaction a: RD
a0 = {Da,Ba,Ra}
Q (a2)
a1 = {Da,Ba,Ca1}
a3 = {Da,Ba,Ca3}
Q (a3)
Q (a4)
a2 = {Da,Ba,Ca2}
a4 = {Da,Ba,Ca4}
a5 = {Da,Ba}
COLC Packet: WDA Precharge Offset
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
The WRA precharge (triggered by the automatic retire) is equivalent to a PRER command here
ROW2
..ROW0
ACT a0
PRER a5
t RTR
COL4
..COL0
WR a1
WRA a2
t OFFP
retire (a1) retire (a2)
MSK (a1) MSK (a2)
DQA8..0
DQB8..0
D (a1)
Transaction a: WR
ACT b0
a0 = {Da,Ba,Ra}
D (a2)
a1 = {Da,Ba,Ca1}
a2 = {Da,Ba,Ca2}
a5 = {Da,Ba}
COLX Packet: PREX Precharge Offset
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
The PREX precharge command is equivalent to a PRER command here
ROW2
..ROW0
ACT a0
PRER a5
ACT b0
t OFFP
COL4
..COL0
RD a1
RD a2
RD a3
DQA8..0
DQB8..0
Q (a1)
Transaction a: RD
24
RD a4
PREX a5
a0 = {Da,Ba,Ra}
Q (a2)
a1 = {Da,Ba,Ca1}
a3 = {Da,Ba,Ca3}
Data Sheet E0251N20 (Ver. 2.0)
Q (a3)
Q (a4)
a2 = {Da,Ba,Ca2}
a4 = {Da,Ba,Ca4}
a5 = {Da,Ba}
µPD488588FF-C80-40
13. Read Transaction - Example
Figure 13-1 shows an example of a read transaction. It begins by activating a bank with an ACT a0 command in an
ROWA packet. A time tRCD later a RD a1 command is issued in a COLC packet. Note that the ACT command
includes the device, bank, and row address (abbreviated as a0) while the RD command includes device, bank, and
column address (abbreviated as a1). A time tCAC after the RD command the read data dualoct Q (a1) is returned by
the device. Note that the packets on the ROW and COL pins use the end of the packet as a timing reference point,
while the packets on the DQA/DQB pins use the beginning of the packet as a timing reference point.
A time tCC after the first COLC packet on the COL pins a second is issued. It contains a RD a2 command. The a2
address has the same device and bank address as the a1 address (and a0 address), but a different column address.
A time tCAC after the second RD command a second read data dualoct Q(a2) is returned by the device.
Next, a PRER a3 command is issued in an ROWR packet on the ROW pins. This causes the bank to precharge so
that a different row may be activated in a subsequent transaction or so that an adjacent bank may be activated. The
a3 address includes the same device and bank address as the a0, a1, and a2 addresses. The PRER command
must occur a time tRAS or more after the original ACT command (the activation operation in any DRAM is destructive,
and the contents of the selected row must be restored from the two associated sense amps of the bank during the
tRAS interval). The PRER command must also occur a time tRDP or more after the last RD command. Note that the
tRDP value shown is greater than the tRDP,MIN specification in “36.Timing Parameters”. This transaction example reads
two dualocts, but there is actually enough time to read three dualocts before tRDP becomes the limiting parameter
rather than tRAS. If four dualocts were read, the packet with PRER would need to shift right (be delayed) by one tCYCLE
(note-this case is not shown).
Finally, an ACT b0 command is issued in an ROWR packet on the ROW pins. The second ACT command must
occur a time tRC or more after the first ACT command and a time tRP or more after the PRER command. This ensures
that the bank and its associated sense amps are precharged. This example assumes that the second transaction
has the same device and bank address as the first transaction, but a different row address. Transaction b may not
be started until transaction a has finished. However, transactions to other banks or other devices may be issued
during transaction a.
Figure 13-1 Read Transaction Example
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
t RC
ROW2
..ROW0
ACT a0
PRER a3
t RAS
COL4
..COL0
RD a1
t RCD
t RP
RD a2
t CC
DQA8..0
DQB8..0
t RDP
Q (a1)
t CAC
Transaction a: RD
Transaction b: xx
ACT b0
a0 = {Da,Ba,Ra}
b0 = {Da,Ba,Rb}
Q (a2)
t CAC
a1 = {Da,Ba,Ca1}
a2 = {Da,Ba,Ca2}
Data Sheet E0251N20 (Ver. 2.0)
a3 = {Da,Ba}
25
µPD488588FF-C80-40
14. Write Transaction - Example
Figure 14-1 shows an example of a write transaction. It begins by activating a bank with an ACT a0 command in an
ROWA packet. A time tRCD - tRTR later a WR a1 command is issued in a COLC packet (note that the tRCD interval is
measured to the end of the COLC packet with the first retire command). Note that the ACT command includes the
device, bank, and row address (abbreviated as a0) while the WR command includes device, bank, and column
address (abbreviated as a1). A time tCWD after the WR command the write data dualoct D(a1) is issued. Note that
the packets on the ROW and COL pins use the end of the packet as a timing reference point, while the packets on
the DQA/DQB pins use the beginning of the packet as a timing reference point.
A time tCC after the first COLC packet on the COL pins a second COLC packet is issued. It contains a WR a2
command. The a2 address has the same device and bank address as the a1 address (and a0 address), but a
different column address. A time tCWD after the second WR command a second write data dualoct D(a2) is issued.
A time tRTR after each WR command an optional COLM packet MSK (a1) is issued, and at the same time a COLC
packet is issued causing the write buffer to automatically retire. See Figure 15-1 for more detail on the write/retire
mechanism. If a COLM packet is not used, all data bytes are unconditionally written. If the COLC packet which
causes the write buffer to retire is delayed, then the COLM packet (if used) must also be delayed.
Next, a PRER a3 command is issued in an ROWR packet on the ROW pins. This causes the bank to precharge so
that a different row may be activated in a subsequent transaction or so that an adjacent bank may be activated. The
a3 address includes the same device and bank address as the a0, a1, and a2 addresses. The PRER command
must occur a time tRAS or more after the original ACT command (the activation operation in any DRAM is destructive,
and the contents of the selected row must be restored from the two associated sense amps of the bank during the
tRAS interval).
A PRER a3 command is issued in an ROWR packet on the ROW pins. The PRER command must occur a time t RTP
or more after the last COLC which causes an automatic retire.
Finally, an ACT b0 command is issued in an ROWR packet on the ROW pins. The second ACT command must
occur a time tRC or more after the first ACT command and a time tRP or more after the PRER command. This ensures
that the bank and its associated sense amps are precharged. This example assumes that the second transaction
has the same device and bank address as the first transaction, but a different row address. Transaction b may not
be started until transaction a has finished. However, transactions to other banks or other devices may be issued
during transaction a.
Figure 14-1 Write Transaction Example
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
t RC
ROW2
..ROW0
ACT a0
PRER a3
t RCD
ACT b0
t RAS
COL4
..COL0
WR a1
WR a2
t RP
t RTR
DQA8..0
DQB8..0
t RTR
D (a1)
t CC
t RTP
retire (a1) retire (a2)
MSK (a1) MSK (a2)
D (a2)
t CWD
t CWD
Transaction a: WR
Transaction b: xx
26
a0 = {Da,Ba,Ra}
b0 = {Da,Ba,Rb}
a1 = {Da,Ba,Ca1}
a2 = {Da,Ba,Ca2}
Data Sheet E0251N20 (Ver. 2.0)
a3 = {Da,Ba}
µPD488588FF-C80-40
15. Write/Retire - Examples
The process of writing a dualoct into a sense amp of an RDRAM bank occurs in two steps. The first step consists of
transporting the write command, write address, and write data into the write buffer. The second step happens when
the RDRAM automatically retires the write buffer (with an optional bytemask) into the sense amp. This two-step write
process reduces the natural turn-around delay due to the internal bidirectional data pins.
Figure 15-1 (left) shows an example of this two step process. The first COLC packet contains the WR command
and an address specifying device, bank and column. The write data dualoct follows a time tCWD later. This
information is loaded into the write buffer of the specified device. The COLC packet which follows a time tRTR later
will retire the write buffer. The retire will happen automatically unless (1) a COLC packet is not framed (no COLC
packet is present and the S bit is zero), or (2) the COLC packet contains a RD command to the same device. If the
retire does not take place at time tRTR after the original WR command, then the device continues to frame COLC
packets, looking for the first that is not a RD directed to itself. A bytemask MSK(a1) may be supplied in a COLM
packet aligned with the COLC that retires the write buffer at time tRTR after the WR command.
The memory controller must be aware of this two-step write/retire process. Controller performance can be
improved, but only if the controller design accounts for several side effects.
Figure 15-1 (right) shows the first of these side effects. The first COLC packet has a WR command which loads the
address and data into the write buffer. The third COLC causes an automatic retire of the write buffer to the sense
amp. The second and fourth COLC packets (which bracket the retire packet) contain RD commands with the same
device, bank and column address as the original WR command. In other words, the same dualoct address that is
written is read both before and after it is actually retired. The first RD returns the old dualoct value from the sense
amp before it is overwritten. The second RD returns the new dualoct value that was just written.
Figure 15-1 Normal Retire (left) and Retire/Read Ordering (right)
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T23
0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23
CTM/CFM
ROW2
..ROW0
CTM/CFM
Retire is automatic here unless:
(1) No COLC packet (S=0) or
(2) COLC packet is RD to device Da
This RD gets the old data
This RD gets the new data
ROW2
..ROW0
t CAC
t CAC
COL4
..COL0
WR a1
retire (a1)
MSK (a1)
COL4
..COL0
WR a1
t RTR
DQA8..0
DQB8..0
retire (a1)
MSK (a1)
RD c1
t RTR
D (a1)
t CWD
Transaction a: WR
RD b1
a1= {Da,Ba,Ca1}
DQA8..0
DQB8..0
D (a1)
t CWD
Transaction a: WR
Transaction b: RD
Transaction c: RD
Q (b1)
Q(
a1= {Da,Ba,Ca1}
b1= {Da,Ba,Ca1}
c1= {Da,Ba,Ca1}
Figure 15-2 (left) shows the result of performing a RD command to the same device in the same COLC packet slot
that would normally be used for the retire operation. The read may be to any bank and column address; all that
matters is that it is to the same device as the WR command. The retire operation and MSK(a1) will be delayed by a
time tPACKET as a result. If the RD command used the same bank and column address as the WR command, the old
data from the sense amp would be returned. If many RD commands to the same device were issued instead of the
single one that is shown, then the retire operation would be held off an arbitrarily long time. However, once a RD to
another device or a WR or NOCOP to any device is issued, the retire will take place. Figure 15-2 (right) illustrates a
situation in which the controller wants to issue a WR-WR-RD COLC packet sequence, with all commands addressed
to the same device, but addressed to any combination of banks and columns.
The RD will prevent a retire of the first WR from automatically happening. But the first dualoct D(a1) in the write
Data Sheet E0251N20 (Ver. 2.0)
27
µPD488588FF-C80-40
buffer will be overwritten by the second WR dualoct D(b1) if the RD command is issued in the third COLC packet.
Therefore, it is required in this situation that the controller issue a NOCOP command in the third COLC packet,
delaying the RD command by a time of tPACKET. This situation is explicitly shown in Table 8-1 for the cases in which
tCCDELAY is equal to tRTR.
Figure 15-2 Retire Held Off by Read (left) and Controller Forces WWR Gap (right)
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23
CTM/CFM
CTM/CFM
The retire operation for a write can be
held off by a read to the same device
ROW2
..ROW0
ROW2
..ROW0
The controller must insert a NOCOP to retire (a1)
to make room for the data (b1) in the write buffer
t CAC
COL4
..COL0
WR a1
RD b1
t CAC
COL4
..COL0
retire (a1)
MSK (a1)
WR a1
WR b1
t RTR + tPACKET
DQA8..0
DQB8..0
retire (a1)
MSK (a1)
RD c1
t RTR
Q (b1)
DQA8..0
D (a1)
D (a1)
D (b1)
DQB8..0
t CWD
Transaction a: WR
Transaction b: RD
t CWD
Transaction a: WR
Transaction b: WR
Transaction c: RD
a1= {Da,Ba,Ca1}
b1= {Da,Bb,Cb1}
a1= {Da,Ba,Ca1}
b1= {Da,Bb,Cb1}
c1= {Da,Bc,Cc1}
Figure 15-3 shows a possible result when a retire is held off for a long time (an extended version of Figure 15-2-left).
After a WR command, a series of six RD commands are issued to the same device (but to any combination of bank
and column addresses). In the meantime, the bank Ba to which the WR command was originally directed is
precharged, and a different row Rc is activated. When the retire is automatically performed, it is made to this new
row, since the write buffer only contains the bank and column address, not the row address. The controller can
insure that this doesn’t happen by never precharging a bank with an unretired write buffer. Note that in a system with
more than one RDRAM, there will never be more than two RDRAMs with unretired write buffers. This is because a
WR command issued to one device automatically retires the write buffers of all other devices written a time tRTR
before or earlier.
Figure 15-3 Retire Held Off by Reads to Same Device, Write Buffer Retired to New Row
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
The retire operation puts the
write data in the new row
t RC
ROW2
..ROW0
ACT a0
PRER a2
ACT c0
t RAS
COL4
..COL0
WR a1
t RCD
DQA8..0
DQB8..0
RD b2
RD b3
Transaction c: WR
RD b4
RD b5
RD b6
retire (a1)
MSK (a1)
t RTR
D (a1)
Transaction a: WR
Transaction b: RD
28
t RP
RD b1
Q (b1)
Q (b2)
t CWD
t CAC
a1 = {Da,Ba,Ca1}
a2 = {Da,Ba}
a0 = {Da,Ba,Ra}
b1 = {Da,Bb,Cb1}
b2 = {Da,Bb,Cb2}
b3= {Da,Bb,Cb3}
b5 = {Da,Bb,Cb5}
b4 = {Da,Bb,Cb4}
b6 = {Da,Bb,Cb6}
c0 = {Da,Ba,Rc}
Data Sheet E0251N20 (Ver. 2.0)
Q (b3)
Q (b4)
Q (b5)
WARNING
This sequence is hazardous
and must be used with caution
µPD488588FF-C80-40
16. Interleaved Write - Example
Figure 16-1 shows an example of an interleaved write transaction. Transactions similar to the one presented in
Figure 14-1 are directed to non-adjacent banks of a single RDRAM. This allows a new transaction to be issued once
every tRR interval rather than once every tRC interval (four times more often). The DQ data pin efficiency is 100% with
this sequence.
With two dualocts of data written per transaction, the COL, DQA, and DQB pins are fully utilized. Banks are
precharged using the WRA autoprecharge option rather than the PRER command in an ROWR packet on the ROW
pins.
In this example, the first transaction is directed to device Da and bank Ba. The next three transactions are directed
to the same device Da, but need to use different, non-adjacent banks Bb, Bc, Bd so there is no bank conflict. The
fifth transaction could be redirected back to bank Ba without interference, since the first transaction would have
completed by then (tRC has elapsed). Each transaction may use any value of row address (Ra, Rb, ...) and column
address (Ca1, Ca2, Cb1, Cb2, ...).
Figure 16-1 Interleaved Write Transaction with Two Dualoct Data Length
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
Transaction e can use the
same bank as transaction a
t RC
ROW2
..ROW0
ACT b0
ACT a0
ACT c0
ACT d0
ACT e0
t RCD
COL4
..COL0
WR z1
WRA z2
MSK (y1) MSK (y2)
ACT f0
t RR
WR a1
WRA a2
WR b1
WRA b2
WR c1
WRA c2
MSK (z1) MSK (z2) MSK (a1) MSK (a2) MSK (b1) MSK (b2)
WR d1
WR d2
WR e1
WR e2
MSK (c1) MSK (c2) MSK (d1) MSK (d2)
t CWD
DQA8..0
DQB8..0
D (x2)
D (y1)
D (y2)
Transaction y: WR
Transaction z: WR
Transaction a: WR
Transaction b: WR
Transaction c: WR
Transaction d: WR
Transaction e: WR
Transaction f: WR
D (z1)
D (z2)
D (a1)
y0 = {Da,Ba+4,Ry}
z0 = {Da,Ba+6,Rz}
a0 = {Da,Ba,Ra}
b0 = {Da,Ba+2,Rb}
c0 = {Da,Ba+4,Rc}
d0 = {Da,Ba+6,Rd}
e0 = {Da,Ba,Re}
f0 = {Da,Ba+2,Rf}
D (a2)
D (b1)
y1 = {Da,Ba+4,Cy1}
z1 = {Da,Ba+6,Cz1}
a1 = {Da,Ba,Ca1}
b1 = {Da,Ba+2,Cb1}
c1 = {Da,Ba+4,Cc1}
d1 = {Da,Ba+6,Cd1}
e1 = {Da,Ba,Ce1}
f1 = {Da,Ba+2,Cf1}
Data Sheet E0251N20 (Ver. 2.0)
D (b2)
D(c1)
y2= {Da,Ba+4,Cy2}
z2= {Da,Ba+6,Cz2}
a2= {Da,Ba,Ca2}
b2= {Da,Ba+2,Cb2}
c2= {Da,Ba+4,Cc2}
d2= {Da,Ba+6,Cd2}
e2= {Da,Ba,Ce2}
f2= {Da,Ba+2,Cf2}
D (c2)
D (d1)
Q(
y3 = {Da,Ba+4}
z3 = {Da,Ba+6}
a3 = {Da,Ba}
b3 = {Da,Ba+2}
c3 = {Da,Ba+4}
d3 = {Da,Ba+6}
e3 = {Da,Ba}
f3 = {Da,Ba+2}
29
µPD488588FF-C80-40
17. Interleaved Read - Example
Figure 17-1 shows an example of interleaved read transactions. Transactions similar to the one presented in Figure
13-1 are directed to non-adjacent banks of a single RDRAM. The address sequence is identical to the one used in
the previous write example. The DQ data pins efficiency is also 100%. The only difference with the write example
(aside from the use of the RD command rather than the WR command) is the use of the PREX command in a COLX
packet to precharge the banks rather than the RDA command. This is done because the PREX is available for a
readtransaction but is not available for a masked write transaction.
Figure 17-1 Interleaved Read Transaction with Two Dualoct Data Length
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
Transaction e can use the
same bank as transaction a
t RC
ROW2
..ROW0
ACT a0
ACT b0
ACT c0
ACT d0
ACT e0
t RCD
ACT f0
t RR
COL4
..COL0
RD z1
RD z2
PREX y3
RD a1
RD a2
PREX z3
DQA8..0
DQB8..0
Q (x2)
Q (y1)
Q (y2)
Q (z1)
RD b1
RD b2
PREX a3
RD c1
RD c2
PREX b3
RD d1
RDd2
PREX c3
RD e1
RD e2
PREX d3
Q (a1)
Q (a2)
Q (b1)
Q (b2)
Q (c1)
Q (c2)
Q (d1)
t CAC
Transaction y: RD
Transaction z: RD
Transaction a: RD
Transaction b: RD
Transaction c: RD
Transaction d: RD
Transaction e: RD
Transaction f: RD
30
Q (z2)
y0 = {Da,Ba+4,Ry}
z0 = {Da,Ba+6,Rz}
a0 = {Da,Ba,Ra}
b0 = {Da,Ba+2,Rb}
c0 = {Da,Ba+4,Rc}
d0 = {Da,Ba+6,Rd}
e0 = {Da,Ba,Re}
f0 = {Da,Ba+2,Rf}
y1 = {Da,Ba+4,Cy1}
z1 = {Da,Ba+6,Cz1}
a1 = {Da,Ba,Ca1}
b1 = {Da,Ba+2,Cb1}
c1 = {Da,Ba+4,Cc1}
d1 = {Da,Ba+6,Cd1}
e1 = {Da,Ba,Ce1}
f1 = {Da,Ba+2,Cf1}
Data Sheet E0251N20 (Ver. 2.0)
y2= {Da,Ba+4,Cy2}
z2= {Da,Ba+6,Cz2}
a2= {Da,Ba,Ca2}
b2= {Da,Ba+2,Cb2}
c2= {Da,Ba+4,Cc2}
d2= {Da,Ba+6,Cd2}
e2= {Da,Ba,Ce2}
f2= {Da,Ba+2,Cf2}
y3 = {Da,Ba+4}
z3 = {Da,Ba+6}
a3 = {Da,Ba}
b3 = {Da,Ba+2}
c3 = {Da,Ba+4}
d3 = {Da,Ba+6}
e3 = {Da,Ba}
f3 = {Da,Ba+2}
µPD488588FF-C80-40
18. Interleaved RRWW - Example
Figure 18-1 shows a steady-state sequence of 2-dualoct RD/RD/WR/WR.. transactions directed to non-adjacent
banks of a single RDRAM. This is similar to the interleaved write and read examples in Figure 16-1 and Figure 17-1
except that bubble cycles need to be inserted by the controller at read/write boundaries. The DQ data pin efficiency
for the example in Figure 18-1 is 32/42 or 76%. If there were more RDRAMs on the Channel, the DQ pin efficiency
would approach 32/34 or 94% for the two-dualoct RRWW sequence (this case is not shown).
In Figure 18-1, the first bubble type tCBUB1 is inserted by the controller between a RD and WR command on the COL
pins. This bubble accounts for the round-trip propagation delay that is seen by read data, and is explained in detail in
Figure 4-1. This bubble appears on the DQA and DQB pins as tDBUB1 between a write data dualoct D and read data
dualoct Q. This bubble also appears on the ROW pins as tRBUB1.
The second bubble type tCBUB2 is inserted (as a NOCOP command) by the controller between a WR and RD
command on the COL pins when there is a WR-WR-RD sequence to the same device. This bubble enables write
data to be retired from the write buffer without being lost, and is explained in detail in Figure 15-2. There would be no
bubble if address c0 and address d0 were directed to different devices. This bubble appears on the DQA and DQB
pins as tDBUB2 between a write data dualoct D and read data dualoct Q. This bubble also appears on the ROW pins
as tRBUB2.
Figure 18-1 Interleaved RRWW Sequence with Two Dualoct Data Length
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
ROW2
..ROW0
ACT a0
ACT b0
ACT c0
t CBUB2
COL4
..COL0
RD z1
tDBUB1
DQA8..0
DQB8..0
Transaction e can use the
same bank as transaction a
ACT d0
ACT e0
t RBUB2
t RBUB1
t CBUB1
RD z2
RD a1
RD a2
PREX z3
WR b1
MSK (y2)
t CBUB2
WRA b2
WR c1
WRA c2
PREX a3 MSK (b1) MSK (b2)
NOCOP
NOCOP
MSK (c1) MSK (c2)
t DBUB2
Transaction y: WR
Transaction z: RD
Transaction a: RD
Transaction b: WR
Transaction c: WR
Transaction d: RD
Transaction e: RD
Transaction f: WR
RD f
t DBUB1
Q (z1)
D (y2)
RDd0
Q (z2)
y0 = {Da,Ba+4,Ry}
z0 = {Da,Ba+6,Rz}
a0 = {Da,Ba,Ra}
b0 = {Da,Ba+2,Rb}
c0 = {Da,Ba+4,Rc}
d0 = {Da,Ba+6,Rd}
e0 = {Da,Ba,Re}
f0 = {Da,Ba+2,Rf}
Q (a1)
Q (a2)
y1 = {Da,Ba+4,Cy1}
z1 = {Da,Ba+6,Cz1}
a1 = {Da,Ba,Ca1}
b1 = {Da,Ba+2,Cb1}
c1 = {Da,Ba+4,Cc1}
d1 = {Da,Ba+6,Cd1}
e1 = {Da,Ba,Ce1}
f1 = {Da,Ba+2,Cf1}
Data Sheet E0251N20 (Ver. 2.0)
D (b1)
D (b2)
D (c1)
y2= {Da,Ba+4,Cy2}
z2= {Da,Ba+6,Cz2}
a2= {Da,Ba,Ca2}
b2= {Da,Ba+2,Cb2}
c2= {Da,Ba+4,Cc2}
d2= {Da,Ba+6,Cd2}
e2= {Da,Ba,Ce2}
f2= {Da,Ba+2,Cf2}
D (c2)
y3 = {Da,Ba+4}
z3 = {Da,Ba+6}
a3 = {Da,Ba}
b3 = {Da,Ba+2}
c3 = {Da,Ba+4}
d3 = {Da,Ba+6}
e3 = {Da,Ba}
f3 = {Da,Ba+2}
31
µPD488588FF-C80-40
19. Control Register Transactions
The RDRAM has two CMOS input pins SCK and CMD and two CMOS input/output pins SIO0 and SIO1. These
provide serial access to a set of control registers in the RDRAM. These control registers provide configuration
information to the controller during the initialization process. They also allow an application to select the appropriate
operating mode of the RDRAM. SCK (serial clock) and CMD (command) are driven by the controller to all RDRAMs
in parallel. SIO0 and SIO1 are connected (in a daisy chain fashion) from one RDRAM to the next. In normal
operation, the data on SIO0 is repeated on SIO1, which connects to SIO0 of the next RDRAM (the data is repeated
from SIO1 to SIO0 for a read data packet). The controller connects to SIO0 of the first RDRAM.
Write and read transactions are each composed of four packets, as shown in Figure 19-1 and Figure 19-2. Each
packet consists of 16 bits, as summarized in Table 20-1 and Table 20-2. The packet bits are sampled on the falling
edge of SCK. A transaction begins with a SRQ (Serial Request) packet. This packet is framed with a 11110000
pattern on the CMD input (note that the CMD bits are sampled on both the falling edge and the rising edge of SCK).
The SRQ packet contains the SOP3..SOP0 (Serial Opcode) field, which selects the transaction type. The
SDEV5..SDEV0 (Serial Device address) selects one of the 32 RDRAMs. If SBC (Serial Broadcast) is set, then all
RDRAMs are selected. The SA (Serial Address) packet contains a 12 bit address for selecting a control register.
A write transaction has a SD (Serial Data) packet next. This contains 16 bits of data that is written into the selected
control register. A SINT (Serial Interval) packet is last, providing some delay for any side-effects to take place. A
read transaction has a SINT packet, then a SD packet. This provides delay for the selected RDRAM to access the
control register. The SD read data packet travels in the opposite direction (towards the controller) from the other
packet types. The SCK cycle time will accommodate the total delay.
Figure 19-1 Serial Write (SWR) Transaction to Control Register
T 20
T4
SCK
T 36
T 52
T 68
1
0
CMD
next transaction
1111 0000
00000000...00000000
00000000...00000000
00000000...00000000
00000000...00000000
1
1111
SIO0
0
1
SRQ - SWR command
SA
SD
SINT
0
Each packet is repeated
from SIO0 to SIO1
SIO1
SRQ - SWR command
1
SA
SD
SINT
0
Figure 19-2 Serial Read (SRD) Transaction Control Register
SCK
T 20
T4
T 36
T 52
T 68
1
0
CMD
1111 0000
next transaction
00000000...00000000
00000000...00000000
SRQ - SRD command
SA
SINT
1111
0
controller drives
0 on SIO0
0
SD
1
0
non addressed RDRAMs pass
0/SD15..SD0/0 from SIO1 to SIO0
First 3 packets are repeated
from SIO0 to SIO1
SRQ - SRD command
1
00000000...00000000
addressed RDRAM devices
0/SD15..SD0/0 on SIO0
SIO 0
SIO 1
00000000...00000000
SA
SINT
0
SD
0
1
0
0
32
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
20. Control Register Packets
Figure 20-1 SETR, CLRR, SETF Transaction
Table 20-1 summarizes the formats of the four packet
T4
types for control register transactions. Table 20-2
T 20
1
SCK
summarizes the fields that are used within the packets.
0
Figure 20-1 shows the transaction format for the SETR,
1
CLRR, and SETF commands. These transactions consist
CMD
1111 0000
00000000...00000000
0
of a single SRQ packet, rather than four packets like the
SWR and SRD commands. The same framing sequence
1
SIO0
on the CMD input is used, however. These commands are
SRQ packet - SETR/CLRR/SETF
0
The packet is repeated
from SIO0 to SIO1
used during initialization prior to any control register read
or write transactions.
SIO1
1
SRQ packet - SETR/CLRR/SETF
0
Table 20-1 Control Register Packet Formats
SCK
Cycle
SIO0 or
SIO1
for SRQ
SIO0 or
SIO1
for SA
SIO0 or
SIO1
for SINT
SIO0 or
SIO1
for SD
SCK
Cycle
SIO0 or
SIO1
for SRQ
SIO0 or
SIO1
for SA
SIO0 or
SIO1
for SINT
SIO0 or
SIO1
for SD
0
rsrv
rsrv
0
SD15
8
SOP1
SA7
0
SD7
1
rsrv
rsrv
0
SD14
9
SOP0
SA6
0
SD6
2
rsrv
rsrv
0
SD13
10
SBC
SA5
0
SD5
3
rsrv
rsrv
0
SD12
11
SDEV4
SA4
0
SD4
4
rsrv
SA11
0
SD11
12
SDEV3
SA3
0
SD3
5
SDEV5
SA10
0
SD10
13
SDEV2
SA2
0
SD2
6
SOP3
SA9
0
SD9
14
SDEV1
SA1
0
SD1
7
SOP2
SA8
0
SD8
15
SDEV0
SA0
0
SD0
Table 20-2 Field Description for Control Register Packets
Field
Description
rsrv
Reserved. Should be driven as “0” by controller.
SOP3..SOP0
0000 - SRD. Serial read of control register {SA11..SA0} of RDRAM {SDEV5..SDEV0}.
0001 - SWR. Serial write of control register {SA11..SA0} of RDRAM {SDEV5..SDEV0}.
0010 - SETR. Set Reset bit, all control registers assume their reset values. Note 16 tSCYCLE delay until CLRR
command.
0100 - SETF. Set fast (normal) clock mode. 4 tSCYCLE delay until next command.
1011 - CLRR. Clear Reset bit, all control registers retain their reset values. Note 4 tSCYCLE delay until next
command.
1111 - NOP. No serial operation.
0011, 0101 – 1010, 1100 – 1110 – RSRV. Reserved encodings.
SDEV5..SDEV0
Serial device. Compared to SDEVID5..SDEVID0 field of INIT control register field to select the RDRAM to
which the transaction is directed.
SBC
Serial broadcast. When set, RDRAMs ignore {SDEV5..SDEV0} for RDRAM selection.
SA11..SA0
Serial address. Selects which control register of the selected RDRAM is read or written.
SD15..SD0
Serial data. The 16 bits of data written to or read from the selected control register of the selected RDRAM.
Note The SETR and CLRR commands must always be applied in two successive transactions to RDRAMs; i.e. they may not be
used in isolation. This is called “SETR/CLRR Reset”.
Data Sheet E0251N20 (Ver. 2.0)
33
µPD488588FF-C80-40
21. Initialization
Figure 21-1 SIO Pin Reset Sequence
T0
T 16
1
SCK
0
1
CMD
00001100
00000000...00000000
0
1
SIO0
0000000000000000
The packet is repeated
from SIO0 to SIO1
SIO1
0
1
0000000000000000
0
Initialization refers to the process that a controller must go through after power is applied to the system or the system
is reset. The controller prepares the RDRAM sub-system for normal Channel operation by (primarily) using a
sequence of control register transactions on the serial CMOS pins. The following steps outline the sequence seen by
the various memory subsystem components (including the RDRAM components) during initialization. This sequence
is available in the form of reference code. Contact Rambus Inc. for more information.
1.0 Start Clocks
This step calculates the proper clock frequencies for PClk (controller logic), SynClk (RAC block), RefClk (DRCG
component), CTM (RDRAM component), and SCK (SIO block).
2.0 RAC Initialization
This step causes the INIT block to generate a sequence of pulses which resets the RAC, performs RAC
maintainance operations, and measures timing intervals in order to ensure clock stability.
3.0 RDRAM Initialization
This stage performs most of the steps needed to initialize the RDRAMs. The rest are performed in stages 5.0,
6.0, and 7.0. All of the steps in 3.0 are carried out through the SIO block interface.
3.1/3.2 SIO Reset
After a delay of tPAUSE from step 1.0, this reset operation is performed before any SIO control register read or
write transactions. It clears six registers (TEST34, CCA, CCB, SKIP, TEST78, and TEST79) and places the
INIT register into a special state (all bits cleared except SKP and SDEVID fields are set to ones).
3.3 Write TEST77 Register
The TEST77 register must be explicitly written with zeros before any other registers are read or written.
3.4 Write TCYCLE Register
The TCYCLE register is written with the cycle time tCYCLE of the CTM clock (for Channel and RDRAMs) in
units of 64ps. The tCYCLE value is determined in stage 1.0.
3.5 Write SDEVID Register
The SDEVID (serial device identification) register of the RDRAM is written with a unique address value so
that directed SIO read and write transactions can be performed. This address value increases from 0 to 31
according to the distance an RDRAM is from the ASIC component on the SIO bus (the closest RDRAM is
address 0).
34
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
3.6 Write DEVID Register
The DEVID (device identification) register of the RDRAM is written with a unique address value so that
directed memory read and write transactions can be performed. This address value increases from 0 to 31.
The DEVID value is not necessarily the same as the SDEVID value. RDRAMs are sorted into regions of the
same core configuration (number of bank, row, and column address bits and core type).
3.7 Write PDNX, PDNXA Registers
The PDNX and PDNXA registers are written with values that are used to measure the timing intervals
connected with an exit from the PDN (powerdown) power state.
3.8 Write NAPX Register
The NAPX register is written with values that are used to measure the timing intervals connected with an exit
from the NAP power state.
3.9 Write TPARM Register
The TPARM register is written with values which determine the time interval between a COL packet with a
memory read command and the Q packet with the read data on the Channel. The values written set the
RDRAM to the minimum value permitted for the system. This will be adjusted later in stage 6.0.
3.10 Write TCDLY1 Register
The TCDLY1 register is written with values which determine the time interval between a COL packet with a
memory read command and the Q packet with the read data on the Channel. The values written set the
RDRAM to the minimum value permitted for the system. This will be adjusted later in stage 6.0.
3.11 Write TFRM Register
The TFRM register is written with a value that is related to the tRCD parameter for the system. The tRCD
parameter is the time interval between a ROW packet with an activate command and the COL packet with a
read or write command.
3.12 SETR/CLRR
First write the following registers with the indicated values:
TEST78
000416
TEST34
004016
Next, the RDRAM is given a SETR command and a CLRR command through the SIO block. This sequence
performs a second reset operation on the RDRAMs. Then the TEST34 and TEST78 registers are rewritten
with zero, in that order.
3.13 Write CCA and CCB Registers
These registers are written with a value halfway between their minimum and maximum values. This shortens
the time needed for the RDRAMs to reach their steady-state current control values in stage 5.0.
3.14 Powerdown Exit
The RDRAM is in the PDN power state at this point. A broadcast PDNExit command is performed by the SIO
block to place the RDRAMs in the RLX (relax) power state in which they are ready to receive ROW packets.
3.15 SETF
The RDRAM is given a SETF command through the SIO block. One of the operations performed by this step
is to generate a value for the AS (autoskip) bit in the SKIP register and fix the RDRAM to a particular read
domain.
Data Sheet E0251N20 (Ver. 2.0)
35
µPD488588FF-C80-40
4.0 Controller Configuration
This stage initializes the controller block. Each step of this stage will set a field of the ConfigRMC[63:0] bus to the
appropriate value. Other controller implementations will have similar initialization requirements, and this stage
may be used as a guide.
4.1 Initial Read Data Offset
The ConfigRMC bus is written with a value which determines the time interval between a COL packet with a
memory read command and the Q packet with the read data on the Channel. The value written sets RMC.d1
to the minimum value permitted for the system. This will be adjusted later in stage 6.0.
4.2 Configure Row/Column Timing
This step determines the values of the tRAS,MIN , tRP,MIN , tRC,MIN , tRCD,MIN , tRR,MIN , and tPP,MIN RDRAM timing
parameters that are present in the system. The ConfigRMC bus is written with values that will be compatible
with all RDRAM devices that are present.
4.3 Set Refresh Interval
This step determines the values of the tREF,MAX RDRAM timing parameter that are present in the system. The
ConfigRMC bus is written with a value that will be compatible with all RDRAM devices that are present.
4.4 Set Current Control Interval
This step determines the values of the tCCTRL,MAX RDRAM timing parameter that are present in the system.
The ConfigRMC bus is written with a value that will be compatible with all RDRAM devices that are present.
4.5 Set Slew Rate Control Interval
This step determines the values of the tTEMP,MAX RDRAM timing parameter that are present in the system. The
ConfigRMC bus is written with a value that will be compatible with all RDRAM devices that are present.
4.6 Set Bank/Row/Col Address Bits
This step determines the number of RDRAM bank, row, and column address bits that are present in the
system. It also determines the RDRAM core types (independent, doubled, or split) that are present. The
ConfigRMC bus is written with a value that will be compatible with all RDRAM devices that are present.
5.0 RDRAM Current Control
This step causes the INIT block to generate a sequence of pulses which performs RDRAM maintenance
operations.
6.0 RDRAM Core, Read Domain Initialization
This stage completes the RDRAM initialization
6.1 RDRAM Core Initialization
A sequence of 192 memory refresh transactions is performed in order to place the cores of all RDRAMs into
the proper operating state.
6.2 RDRAM Read Domain Initialization
A memory write and memory read transaction is performed to the RDRAM to determine which read domain
the RDRAM occupies. The programmed delay of the RDRAM is then adjusted so the total RDRAM read delay
(propagation delay plus programmed delay) is constant. The TPARM and TCDLY1 registers of the RDRAM is
rewritten with the appropriate read delay values. The ConfigRMC bus is also rewritten with an updated value.
36
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
7.0 Other RDRAM Register Fields
This stage rewrites the INIT register with the final values of the LSR, NSR, and PSR fields.
In essence, the controller must read all the read-only configuration registers of all RDRAMs (or it must read the
SPD device present on each RIMM), it must process this information, and then it must write all the read-write
registers to place the RDRAMs into the proper operating mode.
Initialization Note :
1. During the initialization process, it is necessary for the controller to perform 128 current control operations
(3xCAL, 1xCAL/SAM) and one temperature calibrate operation (TCEN/TCAL) after reset or after powerdown
(PDN) exit.
2. The behavior of µPD488588 at initialization is as follows. It is distinguished by the "S28IECO" bit in the SPD.
S28IECO=1: Upon powerup, the device enters PDN state. The serial operations SETR, CLRR, and SETF
require a SDEVID match.
See the document detailing the reference initialization procedure for more information on how to handle this in
a system.
3. After the step of equalizing the total read delay of the RDRAM has been completed (i.e. after the TCDLY0 and
TCDLY1 fields have been written for the final time), a single final memory read transaction should be made to
the RDRAM in order to ensure that the output pipeline stages have been cleared.
4. The SETF command (in the serial SRQ packet) should only be issued once during the Initialization process,
as should the SETR and CLRR commands.
5. The CLRR command (in the serial SRQ packet) leaves some of the contents of the memory core in an
indeterminate state.
Data Sheet E0251N20 (Ver. 2.0)
37
µPD488588FF-C80-40
22. Control Register Summary
Table 22-1 summarizes the RDRAM control registers. Detail is provided for each control register in Figure 22-1.
Read-only bits which are shaded gray are unused and return zero. Read-write bits which are shaded gray are
reserved and should always be written with zero. The RIMM SPD Application Note (DL-0054) of Rambus Inc.
describes additional read-only configuration registers which are present on Direct RIMMs.
The state of the register fields are potentially affected by the IO Reset operation or the SETR/CLRR operation. This
is indicated in the text accompanying each register diagram.
Table 22-1 Control Register Summary (1/2)
SA11..SA0
02116
Register
INIT
Field
read-write/ read-only
Description
SDEVID
read-write, 6 bits
Serial device ID. Device address for control register read/write.
PSX
read-write, 1 bit
Power select exit. PDN/NAP exit with device addr on DQA5..0.
SRP
read-write, 1 bit
SIO repeater. Used to initialize RDRAM.
NSR
read-write, 1 bit
NAP self-refresh. Enables self-refresh in NAP mode.
PSR
read-write, 1 bit
PDN self-refresh. Enables self-refresh in PDN mode.
LSR
read-write, 1 bit
Low power self-refresh. Enables low power self-refresh.
TEN
read-write, 1 bit
Temperature sensing enable.
TSQ
read-write, 1 bit
Temperature sensing output.
DIS
read-write, 1 bit
RDRAM disable.
IDM
read-write, 1 bit
Interleaved Device Mode enable.
02216
TEST34
TEST34
read-write, 16 bits
Test register. Do not read or write after SIO reset.
02316
CNFGA
REFBIT
read-only, 3 bits
Refresh bank bits. Used for multi-bank refresh.
DBL
read-only, 1 bit
Double. Specifies doubled-bank architecture.
MVER
read-only, 6 bits
Manufacturer version. Manufacturer identification number.
PVER
read-only, 6 bits
Protocol version. Specifies version of Direct protocol supported.
BYT
read-only, 1 bit
Byte. Specifies an 8-bit or 9-bit byte size.
DEVTYP
read-only, 3 bits
Device type. Device can be RDRAM or some other device category.
SPT
read-only, 1 bit
Split-core. Each core half is an individual dependent core.
CORG
read-only, 6 bits
Core organization. Bank, row, column address field sizes.
SVER
read-only, 6 bits
Stepping version. Mask version number.
02416
CNFGB
04016
DEVID
DEVID
read-write, 5 bits
Device ID. Device address for memory read/write.
04116
REFB
REFB
read-write, 4 bits
Refresh bank. Next bank to be refreshed by self-refresh.
04216
REFR
REFR
read-write, 9 bits
Refresh row. Next row to be refreshed by REFA, self-refresh.
04316
CCA
CCA
read-write, 7 bits
Current control A. Controls IOL output current for DQA.
ASYMA
read-write, 2 bits
Asymmetry control. Controls asymmetry of VOL/VOH swing for DQA.
CCB
read-write, 7 bits
Current control B. Controls IOL output current for DQB.
ASYMB
read-write, 2 bits
Asymmetry control. Controls asymmetry of VOL/VOH swing for DQB.
NAPXA
read-write, 5 bits
NAP exit. Specifies length of NAP exit phase A.
NAPX
read-write, 5 bits
NAP exit. Specifies length of NAP exit phase A + phase B.
DQS
read-write, 1 bit
DQ select. Selects CMD framing for NAP/PDN exit.
PDNXA
read-write, 13 bits
PDN exit. Specifies length of PDN exit phase A.
04416
04516
04616
38
CCB
NAPX
PDNXA
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Table 22-1 Control Register Summary (2/2)
SA11..SA0 Register
Field
read-write/ read-only
Description
04716
PDNX
PDNX
read-write, 13 bits
PDN exit. Specifies length of PDN exit phase A + phase B.
04816
TPARM
TCAS
read-write, 2 bits
tCAS-C core parameter. Determines tOFFP datasheet parameter.
TCLS
read-write, 2 bits
tCLS-C core parameter. Determines tCAC and tOFFP parameters.
TCDLY0
read-write, 3 bits
tCDLY0-C core parameter. Programmable delay for read data.
TFRM
read-write, 4 bits
tFRM-C core parameter. Determines ROW - COL packet framing interval.
04916
TFRM
04a16
TCDLY1 TCDLY1
read-write, 3 bits
tCDLY-1 core parameter. Programmable delay for read data.
04c16
TCYCLE TCYCLE
read-write, 14 bits
tCYCLE datasheet parameter. Specifies cycle time in 64ps units.
04b16
SKIP
AS
read-only, 1 bit
Autoskip value established by the SETF command.
MSE
read-write, 1 bit
Manual skip enable. Allows the MS value to override the AS value.
MS
read-write, 1 bit
Manual skip value.
04d16-
TEST77 TEST77
read-write, 16 bits
Test register. Write with zero after SIO reset.
04e16-
TEST78 TEST78
read-write, 16 bits
Test register. Do not read or write after SIO reset.
04f16-
TEST79 TEST79
read-write, 16 bits
Test register. Do not read or write after SIO reset.
08016-Off16
reserved reserved
vendor-specific
Vendor-specific test registers. Do not read or write after SIO reset.
Data Sheet E0251N20 (Ver. 2.0)
39
µPD488588FF-C80-40
Figure 22-1 Control Registers (1/7)
Control Register : INIT
Address : 02116
15
14
13
12
11
10
9
8
7
6
5
IDM
SDE
VID5
DIS
TSQ
TEN
LSR
PSR
NSR
SRP
PSX
0
4
3
2
1
0
SDEVID4..0
Read/write register.
Reset values are undefined except as affected by SIO Reset as noted below. SETR/CLRR Reset does not affect this register.
Field
Reset
value
Description
SDEVID5..0 Serial Device Identification. Compared to SDEVID5..0 serial address field of serial request packet for register
read/write transactions. This determines which RDRAM is selected for the register read or write operation.
3f16
DIS
RDRAM disable. DIS=1 causes RDRAM to ignore NAP/PDN exit sequence, DIS=0 permit normal operation.
This mechanism disables an RDRAM.
TSQ
Temperature Sensing Output. TSQ=1 when a temperature trip point has been exceeded, TSQ=0 when it has
not. TSQ is available during a current control operation (see Figure 25-1).
TEN
Temperature Sensing Enable. TEN=1 enables temperature sensing circuitry, permitting the TSQ bit to be
read to determine if a thermal trip point has been exceeded.
0
LSR
Low Power Self-Refresh. This function is not supported. LSR value must be 0.
0
PSR
PDN Self-Refresh. PSR=1 enables self-refresh in PDN mode. PSR can’t be set while in PDN mode.
0
NSR
NAP Self-Refresh. NSR=1 enables self-refresh in NAP mode. NSR can’t be set while in NAP mode.
0
SRP
SIO Repeater. Controls value on SIO1; SIO1=SIO0 if SRP=1, SIO1=1 if SRP=0.
1
PSX
Power Exit Select. PDN and NAP are exited with (=0) or without (=1) a device address on the DQA5..0 pins.
PDEV5 (on DQA5) selectes broadcast (1) or directed (0) exit. For a dircted exit, PDEV4..0 (on DQA4..0) is
compared to DEVID4..0 to select a device.
Control Register : CNFGA
15
14
13
12
PVER5..0=000001
11
10
0
Address : 02316
9
8
7
6
5
4
MVER5..0=mmmmmm
3
DBL1
2
1
0
REFBIT2..0=101
Read only register.
Field
Description
PVER5..0
Protocol Version. Specifies the Direct Protocol version used by this device:
0 – Reserved
1 – Version 1 protocol.
2 – Version 1 plus Interleaved Device Mode.
3 to 63 – Reserved
MVER5..0
Manufacturer Version. Specifies the manufacturer identification number.
DBL
Doubled-Bank. DBL=1 means the device uses a doubled-bank architecture with adjacent-bank dependency. DBL=0
means no dependency.
REFBIT2..0 Refresh Bank Bits. Specifies the number of bank address bits used by REFA and REFP commands.
Permits multi-bank refresh in future RDRAMs.
Caution In RDRAMs with protocol version 1 PVER[5:0] =000001, the range of the PDNX field (PDNX[2:0] in the PDNX
register) may not be large enough to specify the location of the restricted interval in Figure 23-3. In this case,
the effective tS4 parameter must increase and no row or column packets may overlap the restricted interval.
See Figure 23-3 and Timing conditions table.
40
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Figure 22-1 Control Registers (2/7)
Control Register : CNFGB
15
14
13
12
11
10
Address : 02416
9
SVER5..0=ssssss
8
7
6
5
CORG4..0=01000
4
SPT0
3
2
1
DEVTYP2..0=000
0
BYTB
Read only register.
Field
Description
SVER5..0
Stepping version. Specifies the mask version number of this device.
CORG4..0
Core organization. This field specifies the number of bank (5 bits), row (9 bits), and column (7 bits) address bits.
SPT
Split-core. SPT=1 means the core is split, SPT=0 means it is not.
DEVTYP2..0 Device type. DEVTYP=000 means that this device is an RDRAM.
BYT
Byte width. B=1 means the device reads and writes 9-bit memory bytes.B=0 means 8 bits.
Control Register : TEST34
Address : 02216
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2
1
0
Read/write register.
Reset values of TEST34 is zero (from SIO Reset).
This register are used for testing purposes. It must not be read or written after SIO Reset.
Control Register : DEVID
Address : 04016
15
14
13
12
11
10
9
8
7
6
5
0
0
0
0
0
0
0
0
0
0
0
4
3
DEVID4..0
Read/write register.
Reset value is undefined.
Field
Description
DEVID4..0
Device Identification register. DEVID4..DEVID0 is compared to DR4..DR0, DC4..DC0, and DX4..DX0 fields for all
memory read or write transactions. This determines which RDRAM is selected for the memory read or write
transaction.
Data Sheet E0251N20 (Ver. 2.0)
41
µPD488588FF-C80-40
Figure 22-1 Control Registers (3/7)
Control Register : REFB
Address : 04116
15
14
13
12
11
10
9
8
7
6
5
0
0
0
0
0
0
0
0
0
0
0
4
3
2
1
0
REFB4..0
Read/write register.
Reset
value
Field
Description
REFB4..0
Refresh Bank Register. REFB4..REFB0 is the bank that will be refreshed next during self-refresh. REFB4..0
is incremented after each self-refresh activate and precharge operation pair.
Control Register : REFR
0
Address : 04216
15
14
13
12
11
10
9
0
0
0
0
0
0
0
8
7
6
5
4
3
2
1
0
REFR8..0
Read/write register.
Reset
value
Field
Description
REFR8..0
Refresh Row register. REFR8..REFR0 is the row that will be refreshed next by the REFA command or by
self-refresh. REFR8..0 is incremented when BR4..0=11111 for the REFA command. REFR8..0 is
incremented when REFB4..0=11111 for self-refresh.
Control Register : CCA
0
Address : 04316
15
14
13
12
11
10
9
8
0
0
0
0
0
0
0
0
7
ASYM
A0
6
5
4
3
2
1
0
CCA6..0
Read/write register.
Field
Reset
value
Description
ASYMA0
ASYMA0 control the asymmetry of the VOL/VOH voltage swing about the VREF reference voltage for the
DQA8..0 pins.
ASYMA0
ODF
0
0.00
1
0.12
0
Where ODF is the Over Drive Factor (the extra IOL current sunk by an RSL output when ASYMA0 is set).
CCA6..0
Current Control A. Controls the IOL output current for the DQA8..DQA0 pins.
Control Register : CCB
Address : 04416
15
14
13
12
11
10
9
8
0
0
0
0
0
0
0
0
7
ASYM
B0
6
5
4
3
2
1
0
CCB6..0
Read/write register.
Field
ASYMB0
Reset
value
Description
ASYMB0 control the asymmetry of the VOL/VOH voltage swing about the VREF reference voltage for the
DQB8..0 pins.
ASYMB0
ODF
0
0.00
1
0.12
Where ODF is the Over Drive Factor (the extra IOL current sunk by an RSL output when ASYMB0 is set).
CCB6..0
42
Current Control B. Controls the IOL output current for the DQB8..DQB0 pins.
Data Sheet E0251N20 (Ver. 2.0)
0
µPD488588FF-C80-40
Figure 22-1 Control Registers (4/7)
Control Register : NAPX
15
14
13
12
11
10
0
0
0
0
0
DQS
Address : 04516
9
8
7
6
5
4
3
NAPX4..0
2
1
0
NAPXA4..0
Read/write register.
Reset value is undefined.
Note tSCYCLE is tCYCLE1 (SCK cycle time).
Field
Description
DQ Select. This field specifies the number of SCK cycles (0 ≥ 0.5 cycles, 1 ≥ 1.5 cycles) between the CMD pin
framing sequence and the device selection on DQ5..0. see Figure 23-4. This field must be written with a ”1” for this
RDRAM.
DQS
NAPX4..0
Nap Exit Phase A plus B. This field specifies the number of SCK cycles during the first plus second phases for exiting
NAP mode. It must satisfy:
NAPX•tSCYCLE ≥ NAPXA•tSCYCLE+tNAPXB,MAX
Do not set this field to zero.
NAPXA4..0
Nap Exit Phase A. This field specifies the number of SCK cycles during the first phase for exiting NAP mode. It must
satisfy:
NAPXA•tSCYCLE ≥ tNAPXA,MAX
Do not set this field to zero.
Control Register : PDNXA
15
14
13
0
0
0
12
11
10
Address : 04616
9
8
7
6
5
4
3
2
1
0
PDNXA12..0
Read/write register.
Reset value is undefined.
Field
Description
PDNXA4..0
PDN Exit Phase A. This field specifies the number of (64•SCK cycle) units during the first phase for exiting PDN
mode. It must satisfy:
PDNXA•64•tSCYCLE ≥ tPDNXA,MAX
Do not set this field to zero.
Note – only PDNXA4..0 are implemented.
Note – tSCYCLE is tCYCLE1 (SCK cycle time).
Control Register : PDNX
15
14
13
0
0
0
12
11
Address : 04716
10
9
8
7
6
5
4
3
2
1
0
PDNX12..0
Read/write register.
Reset value is undefined.
Field
Description
PDNX2..0
PDN Exit Phase A puls B. This field specifies the number of (256•SCK cycle) units during the first plus second phases
for exiting PDN mode. It should satisfy:
PDNX•256•tSCYCLE ≥ PDNXA•64•tSCYCLE+tPDNXB,MAX
It this equation can’t be satisfied, then the maximum PDNX value should be written, and the tS4 / tH4 timing window will
be modified (see Figure 23-4).
Do not set this field to zero.
Note – only PDNX2..0 are implemented.
Note – tSCYCLE is tCYCLE1 (SCK cycle time).
Data Sheet E0251N20 (Ver. 2.0)
43
µPD488588FF-C80-40
Figure 22-1 Control Registers (5/7)
Control Register : TPARM
Address : 04816
15
14
13
12
11
10
9
8
7
0
0
0
0
0
0
0
0
0
6
5
4
3
TCDLY0
2
1
TCLS
0
TCAL
Read/write register.
Reset value is undefined.
Field
Description
TCDLY0
Specifies the tCDLY0-C core parameter in tCYCLE units. This adds a programmable delay to Q (read data) packets,
permitting round trip read delay to all device to be equalized. This field may be written with the values “010” (2•tCYCLE)
through “101” (5•tCYCLE).
TCLS1..0
Specifies the tCLS-C core parameter in tCYCLE units. Should be “10” (2•tCYCLE).
Specifies the tCAS-C core parameter in tCYCLE units. This should be “10” (2•tCYCLE).
TCAS1..0
The equations relating the core parameters to the datasheet parameters follow:
tCAS-C=2•tCYCLE
tCLS-C=2•tCYCLE
tCPS-C=1•tCYCLE
Not programmable
tOFFP=tCPS-C + tCAS-C + tCLS-C - 1•tCYCLE
=4•tCYCLE
tRCD=tRCD-C + 1•tCYCLE – tCLS-C
=tRCD-C - 1•tCYCLE
tCAC=3•tCYCLE + tCLS-C + tCDLY0-C + tCDLY1-C (see table below programming ranges)
tCDLY0-C
TCDLY1
tCDLY1-C
010
2•tCYCLE
000
0•tCYCLE
7•tCYCLE
not allowed
011
3•tCYCLE
000
0•tCYCLE
8•tCYCLE
8•tCYCLE
011
3•tCYCLE
001
1•tCYCLE
9•tCYCLE
9•tCYCLE
011
3•tCYCLE
010
2•tCYCLE
10•tCYCLE
10•tCYCLE
100
4•tCYCLE
010
2•tCYCLE
11•tCYCLE
11•tCYCLE
101
5•tCYCLE
010
2•tCYCLE
12•tCYCLE
12•tCYCLE
TCDLY0
Control Register : TFRM
tCAC@tCYCLE=3.30 ns tCAC@tCYCLE=2.50 ns
Address : 04916
15
14
13
12
11
10
9
8
7
6
5
4
0
0
0
0
0
0
0
0
0
0
0
0
3
2
1
0
TFRM3..0
Read/write register.
Reset value is undefined.
Field
TFRM3..0
44
Description
Specifies the position of the framing point in tCYCLE units. This value must be greater than or equal to the tFRM,MIN
parameter. This is the minimum offset between a ROW packet (which places a device at ATTN) and the first COL
packet (directed to that device) which must be framed. This field may be written with the value “0111” (7•tCYCLE)
through “1010” (10•tCYCLE). TFRM is usually set to the value which matches the largest tRCD,MIN parameter (modulo
4•tCYCLE) that is present in an RDRAM in the memory system. Thus, if an RDRAM with tRCD,MIN=11•tCYCLE were
present, then TFRM would be programmed to 7•tCYCLE.
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Figure 22-1 Control Registers (6/7)
Control Register : TCDLY1
Address : 04a16
15
14
13
12
11
10
9
8
7
6
5
4
3
0
0
0
0
0
0
0
0
0
0
0
0
0
2
1
0
TCDLY1
Read/write register.
Reset value is undefined.
Field
Description
TCDLY1
Specifies the value of the tCDLY1-C core parameter in tCYCLE units. This adds a programmable delay to Q (read data)
packets, permitting round trip read to delay all devices to be equalized. This field may be written with the values “000”
(0•tCYCLE) through “010” (2•tCYCLE). Refer to TPARM Register for more details.
Control Register : SKIP
Address : 04b16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
AS
MSE
MS
0
0
0
0
0
0
0
0
0
0
Read/write register (except AS field).
Reset value is zero (SIO Reset).
Field
Description
Manual skip (MS must be 1 when MSE=1). > During initialization, the RDRAMs at the furthest point in the fifth read
domain may have selected the AS=0 value, placing them at the closest point in a sixth read domain. Setting the
MSE/MS fields to 1/1 overrides the autoskip value and returns them to the furthest point of the fifth read domain.
MS
Manual skip enable (0=auto, 1=manual ).
MSE
Autoskip. Read-only value determined by autoskip circuit and stored when SETF serial command is received by
RDRAM during initialization. In Figure34-1, AS=1 corresponds to the early Q(a1) packet and AS=0 to the Q(a1) packet
one tCYCLE later for the four uncertain cases.
AS
Control Register : TCYCLE
15
14
0
0
13
12
11
10
Address : 04c16
9
8
7
6
5
4
3
2
1
0
TCYCLE13..0
Read/write register.
Reset value is undefined.
Field
TCYCLE13..0
Description
Specifies the value of the tCYCLE datasheet parameter in 64ps units. For the tCYCLE,MIN of 2.50 ns (2500ps), this field
should be written with the value “0002716” (39•64ps).
Data Sheet E0251N20 (Ver. 2.0)
45
µPD488588FF-C80-40
Figure 22-1 Control Registers (7/7)
Control Register : TEST77
Address : 04d16
Control Register : TEST78
Address : 04e16
Control Register : TEST79
Address : 04f16
15
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Read/write register.
Field
Reset
value
Description
TEST77
It must be written with zero after SIO reset. These registers must only be used for testing purposes.

TEST78
Do not read or written after SIO reset.
0
TEST79
Do not read or written after SIO reset.
0
46
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
23. Power State Management
Table 23-1 summarizes the power states available to a Direct RDRAM. In general, the lowest power states have
the longest operational latencies. For example, the relative power levels of PDN state and STBY state have a ratio of
about 1:110, and the relative access latencies to get read data have a ratio of about 250:1.
PDN state is the lowest power state available. The information in the RDRAM core is usually maintained with selfrefresh; an internal timer automatically refreshes all rows of all banks. PDN has a relatively long exit latency because
the TCLK/RCLK block must resynchronize itself to the external clock signal.
NAP state is another low-power state in which either self-refresh or REFA-refresh are used to maintain the core.
See 24. Refresh for a description of the two refresh mechanisms. NAP has a shorter exit latency than PDN because
the TCLK/RCLK block maintains its synchronization state relative to the external clock signal at the time of NAP
entry. This imposes a limit (tNLIMIT) on how long an RDRAM may remain in NAP state before briefly returning to STBY
or ATTN to update this synchronization state.
Table 23-1 Power State Summary
Power State Description
Blocks consuming power Power state
Description
Blocks consuming power
PDN
Powerdown state.
Self-refresh
NAP
Nap state. Similar to
PDN except lower
wake-up latency.
Self-refresh or
REFA-refresh
TCLK/RCLK-Nap
STBY
Standby state.
Ready for ROW
packets.
REFA-refresh
TCLK/RCLK
ROW demux receiver
ATTN
Attention state.
Ready for ROW and
COL packets.
REFA-refresh
TCLK/RCLK
ROW demux receiver
COL demux receiver
ATTNR
Attention read state.
Ready for ROW and
COL packets.
Sending Q (read data)
packets.
REFA-refresh
TCLK/RCLK
ROW demux receiver
COL demux receiver
DQ mux transmitter
Core power
ATTNW
Attention write state.
Ready for ROW and
COL packets.
Ready for D (write data)
packets.
REFA-refresh
TCLK/RCLK
ROW demux receiver
COL demux receiver
DQ demux receiver
Core power
Data Sheet E0251N20 (Ver. 2.0)
47
µPD488588FF-C80-40
Figure 23-1 summarizes the transition conditions needed for moving between the various power states. Note that
NAP and PDN have been divided into two substates (NAP-A/NAP-S and PDN-A/PDN-S) to account for the fact that a
NAP or PDN exit may be made to either ATTN or STBY states.
Figure 23-1 Power State Transition Diagram
automatic
ATTNR
ATTNW
automatic
automatic
automatic
automatic
automatic
ATTN
RLX
tNLIMIT
NAPR • RLXR
NAP-A
PDEV.CMD•SIO0
NAPR • RLXR
NAP
NAP-S
PDEV.CMD•SIO0
PDNR • RLXR
PDN-A
PDEV.CMD•SIO0
PDNR • RLXR
PDN
NAPR
PDNR
ATTN
PDN-S
PDEV.CMD•SIO0
STBY
SETR/CLRR
Notation:
SETR/CLRR - SETR/CLRR Reset sequence in SRQ packet
PDNR - PDNR command in ROWR packet
NAPR - NAPR command in ROWR packet
RLXR - RLX command in ROWR packet
RLX - RLX command in ROWR,COLC,COLX packets
SIO0 - SIO0 input value
PDEV.CMD - (PDEV=DEVID)•(CMD=01)
ATTN - ROWA packet(non-broadcast) or ROWR packet
(non-broadcast) with ATTN command
At initialization, the SETR/CLRR Reset sequence will put the RDRAM into PDN-S state. The PDN exit sequence
involves an optional PDEV specification and bits on the CMD and SIOIN pins.
Once the RDRAM is in STBY, it will move to the ATTN/ATTNR/ATTNW states when it receives a non-broadcast
ROWA packet or non-broadcast ROWR packet with the ATTN command. The RDRAM returns to STBY from these
three states when it receives a RLX command. Alternatively, it may enter NAP or PDN state from ATTN or STBY
states with a NAPR or PDNR command in an ROWR packet. The PDN or NAP exit sequence involves an optional
PDEV specification and bits on the CMD and SIO0 pins. The RDRAM returns to the ATTN or STBY state it was
originally in when it first entered NAP or PDN.
An RDRAM may only remain in NAP state for a time tNLIMIT. It must periodically return to ATTN or STBY.
The NAPRC command causes a napdown operation if the RDRAM’s NCBIT is set. The NCBIT is not directly visible.
It is undefined on reset. It is set by a NAPR command to the RDRAM, and it is cleared by an ACT command to the
RDRAM. It permits a controller to manage a set of RDRAMs in a mixture of power states.
STBY state is the normal idle state of the RDRAM. In this state all banks and sense amps have usually been left
precharged and ROWA and ROWR packets on the ROW pins are being monitored. When a non-broadcast ROWA
packet or non-broadcast ROWR packet(with the ATTN command) packet addressed to the RDRAM is seen, the
RDRAM enters ATTN state (see the right side of Figure 23-2). This requires a time tSA during which the RDRAM
activates the specified row of the specified bank. A time TFRM•tCYCLE after the ROW packet, the RDRAM will be able
to frame COL packets (TFRM is a control register field – see Figure 22-1(5/7) “TFRM Register”). Once in ATTN
state, the RDRAM will automatically transition to the ATTNW and ATTNR states as it receives WR and RD
commands.
48
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Once the RDRAM is in ATTN, ATTNW, or ATTNR states, it will remain there until it is explicitly returned to the STBY
state with a RLX command. A RLX command may be given in an ROWR, COLC, or COLX packet (see the left side
of Figure 23-2). It is usually given after all banks of the RDRAM have been precharged; if other banks are still
activated, then the RLX command would probably not be given.
If a broadcast ROWA packet or ROWR packet (with the ATTN command) is received, the RDRAM’s power state
doesn’t change. If a broadcast ROWR packet with RLXR command is received, the RDRAM goes to STBY.
Figure 23-2 STBY Entry (left) and STBY Exit (right)
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T23
0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16
CTM/CFM
ROW2
..ROW0
COL4
..COL0
CTM/CFM
ROW2
..ROW0
RLXR
ROP=non-broadcast
ROWA or ROWR/ATTN
a0={d0, b0, r0}
a1={d1, b1, c1}
ROP a0
COP a1
COP a1
COP a1
COP a1
COP a0
XOP a1
XOP a0
COL4
..COL0
RLXC
RLXX
TFRM•tCYCLE
DQA8..0
DQB8..0
A COL packet to device d0
(or any other device) is okay at
(TFRM)•tCYCLE
or later.
DQA8..0
DQB8..0
t SA
t AS
Power
State
ATTN
STBY
Power
State
ATTN
STBY
No COL packets may be
placed in the three
indicated positions; i.e. at
(TFRM-{1,2,3})•tCYCLE.
A COL packet to another device
(d1!=d0) is okay at
(TFRM-4)•tCYCLE
or earlier.
Figure 23-3 shows the NAP entry sequence (left). NAP state is entered by sending a NAPR command in a ROW
packet. A time tASN is required to enter NAP state (this specification is provided for power calculation purposes). The
clock on CTM/CFM must remain stable for a time tCD after the NAPR command.
Figure 23-3 NAP Entry (left) and PDN Entry (right)
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T23
0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14
CTM/CFM
CTM/CFM
a0={d0, b0, r0, c0}
a1={d1, b1, c1, c1}
t CD
ROW2
..ROW0
ROP a0
COL4
..COL0
COP a0
XOP a0
restricted
t CD
ROP a1
(NAPR)
t NPQ
restricted
ROW2
..ROW0
ROP a0
COL4
..COL0
COP a0
XOP a0
restricted
tNPQ
COP a1
XOP a1
DQA8..0
DQB8..0
restricted
COP a1
XOP a1
ROW or COL packets to a device
other than d0 may overlap the
restricted interval.
DQA8..0
DQB8..0
ATTN/STBY Note
ROW or COL packets directed
to device d0 after the restricted
interval will be ignored.
t ASP
t ASN
Power
State
No ROW or COL packets directed
to device d0 may overlap the
restricted interval. No broadcast
ROW packets may overlap
the quiet interval.
ROP a1
(PDNR)
NAP
Power
State
ATTN/STBY Note
PDN
Note The(eventual) NAP/PDN exit will be to the same ATTN/STBY state the RDRAM was in prior to NAP/PDN entry
The RDRAM may be in ATTN or STBY state when the NAPR command is issued. When NAP state is exited, the
RDRAM will return to the original starting state (ATTN or STBY). If it is in ATTN state and a RLXR command is
specified with NAPR, then the RDRAM will return to STBY state when NAP is exited.
Figure 23-3 also shows the PDN entry sequence (right). PDN state is entered by sending a PDNR command in a
ROW packet. A time tASP is required to enter PDN state (this specification is provided for power calculation
purposes). The clock on CTM/CFM must remain stable for a time tCD after the PDNR command.
Data Sheet E0251N20 (Ver. 2.0)
49
µPD488588FF-C80-40
The RDRAM may be in ATTN or STBY state when the PDNR command is issued. When PDN state is exited, the
RDRAM will return to the original starting state (ATTN or STBY). If it is in ATTN state and a RLXR command is
specified with PDNR, then the RDRAM will return to STBY state when PDN is exited. The current- and slew-ratecontrol levels are re-established.
The RDRAM’s write buffer must be retired with the appropriate COP command before NAP or PDN are entered.
Also, all the RDRAM’s banks must be precharged before NAP or PDN are entered. The exception to this is if NAP is
entered with the NSR bit of the INIT register cleared(disabling self-refresh in NAP). The commands for relaxing,
retiring, and precharging may be given to the RDRAM as late as the ROPa0, COPa0, and XOPa0 packets in Figure
23-3. No broadcast packets nor packets directed to the RDRAM entering NAP or PDN may overlay the quiet window.
This window extends for a time tNPQ after the packet with the NAPR or PDNR command.
Figure 23-4 shows the NAP and PDN exit sequences. These sequences are virtually identical; the minor
differences will be highlighted in the following description.
Before NAP or PDN exit, the CTM/CFM clock must be stable for a time tCE. Then, on a falling and rising edge of
SCK, if there is a “01” on the CMD input, NAP or PDN state will be exited. Also, on the falling SCK edge the SIO0
input must be at a 0 for NAP exit and 1 for PDN exit.
If the PSX bit of the INIT register is 0, then a device PDEV5..0 is specified for NAP or PDN exit on the DQA5..0 pins.
This value is driven on the rising SCK edge 0.5 or 1.5 SCK cycles after the original falling edge, depending upon the
value of the DQS bit of the NAPX register. If the PSX bit of the INIT register is 1, then the RDRAM ignores the
PDEV5..0 address packet and exits NAP or PDN when the wake-up sequence is presented on the CMD wire. The
ROW and COL pins must be quiet at a time tS4 / tH4 around the indicated falling SCK edge(timed with the PDNX or
NAPX register fields). After that, ROW and COL packets may be directed to the RDRAM which is now in ATTN or
STBY state.
Figure 23-5 shows the constraints for entering and exiting NAP and PDN states. On the left side, an RDRAM exits
NAP state at the end of cycle T3. This RDRAM may not re-enter NAP or PDN state for an interval of tNU0. The RDRAM
enters NAP state at the end of cycle T13. This RDRAM may not re-exit NAP state for an interval of tNU1. The equations
for these two parameters depend upon a number of factors, and are shown at the bottom of the figure. NAPX is the
value in the NAPX field in the NAPX register.
On the right side of Figure23-4, an RDRAM exits PDN state at the end of cycle T3. This RDRAM may not re-enter
PDN or NAP state for an interval of tPU0. The RDRAM enters PDN state at the end of cycle T13. This RDRAM may not
re-exit PDN state for an interval of tPU1. The equations for these two parameters depend upon a number of factors,
and are shown at the bottom of the figure. PDNX is the value in the PDNX field in the PDNX register.
50
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Figure 23-4 NAP and PDN Exit
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
If PSX=1 in Init register,
then NAP/PDN exit is
broadcast (no PDEV field).
ROW2
..ROW0
COL4
..COL0
t S3 t H3 t S3 t H3
DQA8..0
DQB8..0
t CE
Note 2
Note 2
PDEV5..0
PDEV5..0
No ROW packets may overlap
the restricted interval
ROP
No COL packets may overlap
the restricted interval if device
PDEV is exiting the NAP-A or
PDN-A states
COP
XOP
restricted
ROP
t S4 tH4
restricted
COP
XOP
tS4 tH4
Note 2
DQS=0 Note 2,3
DQS=1
SCK
CMD
0
1
Effective hold becomes
tH4’ = tH4 +[PDNXA•64•tSCYCLE + tPDNXB,MAX] - [PDNX•256•tSCYCLE]
if [PDNX•256•tSCYCLE] < [PDNXA•64•tSCYCLE + tPDNXB,MAX].
Note 1
SIO0
0/1
The packet is repeated
from SIO0 to SIO1
Note 1
SIO1
0/1
(NAPX•t SCYCLE )/(256•PDNX•t SCYCLE )
Power
State
NAP/PDN
Note 4
STBY/ATTN
Note 2
DQS=0
Note 2
DQS=1
Notes 1. Use 0 for NAP exit, 1 for PDN exit
2. Device selection timing slot is selected by DQS field of NAPX register
3. The DQS field must be written with “1” for this RDRAM.
4. Exit to STBY or ATTN depends upon whether RLXR was asserted at NAP or PDN entry time
Figure 23-5 NAP Entry/Exit Windows (left) and PDN Entry/Exit Windows (right)
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15T 16T 17 T 18 T 19
CTM/CFM
CTM/CFM
PDN entry
NAP entry
ROW2
..ROW0
ROW2
..ROW0
NAPR
PDNR
SCK
SCK
PDN exit
NAP exit
CMD
0
0
1
t NU0
no entry to NAP or PDN
1
CMD
0
t NU1
0
1
tPU0
t PU1
no entry to NAP or PDN no exit
no exit
tNU0 =5•t CYCLE +(2+NAPX)•t SCYCLE
t PU0 =5•t CYCLE +(2+256•PDNX)•t SCYCLE
t NU1 =8•t CYCLE - (0.5•t SCYCLE )
t PU1 =8•t CYCLE - (0.5•t SCYCLE )
=23•t CYCLE
if NSR=0
if NSR=1
=23•t CYCLE
Data Sheet E0251N20 (Ver. 2.0)
if PSR=0
if PSR=1
51
µPD488588FF-C80-40
24. Refresh
RDRAMs, like any other DRAM technology, use volatile storage cells which must be periodically refreshed. This is
accomplished with the REFA command. Figure 24-1 shows an example of this.
The REFA command in the transaction is typically a broadcast command (DR4T and DR4F are both set in the
ROWR packet), so that in all devices bank number Ba is activated with row number REFR, where REFR is a control
register in the RDRAM. When the command is broadcast and ATTN is set, the power state of the RDRAMs (ATTN or
STBY) will remain unchanged. The controller increments the bank address Ba for the next REFA command. When
Ba is equal to its maximum value, the RDRAM automatically increments REFR for the next REFA command.
On average, these REFA commands are sent once every tREF / 2 BBIT+RBIT (where BBIT are the number of bank address
bits and RBIT are the number of row address bits) so that each row of each bank is refreshed once every tREF
interval.
The REFA command is equivalent to an ACT command, in terms of the way that it interacts with other packets (see
Table 6-1). In the example, an ACT command is sent after tRR to address b0, a different (non-adjacent) bank than the
REFA command.
A second ACT command can be sent after a time tRC to address c0, the same bank (or an adjacent bank) as the
REFA command.
Note that a broadcast REFP command is issued a time tRAS after the initial REFA command in order to precharge
the refreshed bank in all RDRAMs. After a bank is given a REFA command, no other core operations(activate or
precharge) should be issued to it until it receives a REFP.
It is also possible to interleave refresh transactions (not shown). In the figure, the ACT b0 command would be
replaced by a REFA b0 command. The b0 address would be broadcast to all devices, and would be {Broadcast,
Ba+2,REFR}. Note that the bank address should skip by two to avoid adjacent bank interference. A possible bank
incrementing pattern would be: {12, 10, 5, 3, 0, 14, 9, 7, 4, 2, 13, 11, 8, 6, 1, 15, 28, 26, 21, 19, 16, 30, 25, 23, 20, 18,
29, 27, 24, 22, 17, 31}. Every time bank 31 is reached, a REFA command would automatically increment the REFR
register.
A second refresh mechanism is available for use in PDN and NAP power states. This mechanism is called selfrefresh mode. When the PDN power state is entered, or when NAP power state is entered with the NSR control
register bit set, then self-refresh is automatically started for the RDRAM.
Self-refresh uses an internal time base reference in the RDRAM. This causes an activate and precharge to be
carried out once in every tREF / 2 BBIT+RBIT interval. The REFB and REFR control registers are used to keep track of the
bank and row being refreshed.
Before a controller places an RDRAM into self-refresh mode, it should perform REFA/REFP refreshes until the bank
address is equal to the maximum value. This ensures that no rows are skipped. Likewise, when a controller returns
an RDRAM to REFA/REFP refresh, it should start with the minimum bank address value (zero).
Figure 24-2 illustrates the requirement imposed by the tBURST parameter. After PDN or NAP (when self-refresh is
enabled) power states are exited, the controller must refresh all banks of the RDRAM once during the interval tBURST
after the restricted interval on the ROW and COL buses. This will ensure that regardless of the state of self-refresh
during PDN or NAP, the tREF, MAX parameter is met for all banks. During the tBURST interval, the banks may be
refreshed in a single burst, or they may be scattered throughout the interval. Note that the first and last banks to be
refreshed in the tBURST interval are numbers 12 and 31, in order to match the example refresh sequence.
52
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Figure 24-1 REFA/REFP Refresh Transaction Example
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
t RC
ROW2
..ROW0
REFA a0
ACT b0
REFP a1
t RAS
COL4
..COL0
ACT c0
REFA d0
t RP
t RR
tREF/2BBIT+RBIT
DQA8..0
DQB8..0
Transaction a: REFA
Transaction b: xx
Transaction c: xx
Transaction d: REFA
BBIT = #bank address bits
RBIT = #row address bits
REFB = REFB3..REFB0
REFR = REFR8..REFR0
a1 = {Broadcast,Ba}
a0 = {Broadcast,Ba,REFR}
b0 = {Db, /={Ba,Ba+1,Ba-1}, Rb}
c0 = {Dc, ==Ba, Rc}
d0 = {Broadcast,Ba+1,REFR}
Figure 24-2 NAP/PDN Exit - tBURST Requirement
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
t BURST
ROW2
..ROW0
ROP
COL4
..COL0
COP
XOP
restricted
ROP
REFA b31
32 bank refresh sequence
t S4 tH4
restricted
REFA b12
COP
XOP
tS4 tH4
DQA8..0
DQB8..0
t CE
SCK
CMD
SIO0
0
1
Note 1
0/1
The packet is repeated
from SIO0 to SIO1
SIO1
Note 1
0/1
(NAPX•t SCYCLE )/(256•PDNX•t SCYCLE )
Power
State
NAP/PDN
STBY
Note 2
DQS=0
Note 2
DQS=1
Notes 1. Use 0 for NAP exit, 1 for PDN exit
2. Device selection timing slot is selected by DQS field of NAPX register
Data Sheet E0251N20 (Ver. 2.0)
53
µPD488588FF-C80-40
25. Current and Temperature Control
Figure 25-1 shows an example of a transaction which performs current control calibration. It is necessary to
perform this operation once to every RDRAM in every tCCTRL interval in order to keep the IOL output current in its
proper range.
This example uses four COLX packets with a CAL command. These cause the RDRAM to drive four calibration
packets Q(a0) a time tCAC later. An offset of tRDTOCC must be placed between the Q(a0) packet and read data Q(a1)
from the same device. These calibration packets are driven on the DQA4..3 and DQB4..3 wires. The TSQ bit of the
INIT register is driven on the DQA5 wire during same interval as the calibration packets. The remaining DQA and
DQB wires are not used during these calibration packets. The last COLX packet also contains a SAM command
(concatenated with the CAL command). The RDRAM samples the last calibration packet and adjusts its IOL current
value.
Unlike REF commands, CAL and SAM commands cannot be broadcast. This is because the calibration packets
from different devices would interfere. Therefore, a current control transaction must be sent every tCCTRL /N, where N
is the number of RDRAMs on the Channel. The device field Da of the address a0 in the CAL/SAM command should
be incremented after each transaction.
Figure 25-2 shows an example of a temperature calibration sequence to the RDRAM. This sequence is broadcast
once every tTEMP interval to all the RDRAMs on the Channel. The TCEN and TCAL are ROP commands, and cause
the slew rate of the output drivers to adjust for temperature drift. During the quiet interval tTCQUIET the devices being
calibrated can’t be read, but they can be written.
Figure 25-1 Current Control CAL/SAM Transaction Example
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
Read data from the same
device from an earlier RD
command must be at this
packet position or earier.
ROW2
..ROW0
Read data from a different
device from an earlier RD
command can be anywhere
prior to the Q(a0) packet.
Read data from a different
device from a later RD
command can be anywhere
after to the Q(a0) packet.
Read data from the same
device from a later RD
command must be at this
packet position or later.
t CCTRL
COL4
..COL0
CAL a0
CAL a0
CAL a0
CAL/SAM a0
CAL a2
t CAC
DQA8..0
DQB8..0
t CCSAMTOREAD
Q (a0)
Q (a1)
t READTOCC
Transaction a0: CAL/SAM
Transaction a1: RD
Transaction a2: CAL/SAM
Q (a1)
DQA5 of the first calibrate packet has the inverted TSQ bit of INIT
control register; i.e. logic 0 or high voltage means hot temperature.
When used for monitoring, it should be enabled with the DQA3
bit (current control one value) in case there is no RDRAM present:
HotTemp = /DQA5•DQA3
Note that DQB3 could be used instead of DQA3.
a0 = {Da, Bx}
a1 = {Da, Bx}
a2 = {Da, Bx}
Figure 25-2 Temperature Calibration (TCEN-TCAL) Transactions to RDRAM
T 0 T 1 T 2 T 3 T 4 T 5 T 6 T 7 T 8 T 9 T 10 T 11 T 12T 13 T 14 T 15 T 16T 17 T 18 T 19 T 20T 21 T 22 T 23 T 24T 25 T 26 T 27T 28T 29 T 30 T 31 T 32T 33 T 34 T 35 T 36T 37 T 38 T 39 T 40T 41 T 42 T 43T 44T 45 T 46 T 47
CTM/CFM
t TEMP
ROW2
..ROW0
TCEN
TCAL
t TCEN
COL4
..COL0
DQA8..0
DQB8..0
54
TCEN
t TCAL
t TCQUIET
Any ROW packet may be
placed in the gap between the
ROW packets with the
TCEN and TCAL commands.
CA L
No read data from devices
being calibrated
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
26. Electrical Conditions
Electrical Conditions
Symbol
Parameter and Conditions
MIN.
Tj
Junction temperature under bias
VDD, VDDa
Supply voltage
VDD,N,VDDa,N
Supply voltage droop (DC) during NAP interval (tNLIMT)
VDD,N,VDDa,N
Supply voltage ripple (AC) during NAP interval (tNLIMT)
VCMOS
Supply voltage for CMOS pins (2.5V controllers)
Supply voltage for CMOS pins (1.8V controllers)
VTERM
MAX.
Unit

100
°C
2.50 – 0.13
2.50 + 0.13
V
—
2.0
%
–2.0
+2.0
%
2.50 – 0.13
2.50 + 0.25
V
1.80 – 0.1
1.80 + 0.2
V
Termination voltage
1.80 – 0.1
1.80 + 0.1
V
VREF
Reference voltage
1.40 – 0.2
1.40 + 0.2
V
VDIL
RSL data input - low voltage
VREF – 0.5
VREF – 0.2
V
VDIH
RSL data input - high voltage
VREF + 0.2
VREF + 0.5
V
VDIS
RSL data input swing : VDIS = VDIH – VDIL
ADI
RSL data asymmetry : ADI = [(VDIH – VREF) + (VDIL – VREF)] / VDIS
0.4
1.0
V
0
–20
%
VX
RSL clock input - crossing point of true and complement signals
1.3
1.8
V
VCM
RSL clock input - common mode VCM = (VCIH + VCIL ) / 2
VCIS, CTM
RSL clock input swing : VCIS = VCIH – VCIL (CTM, CTMN pins).
1.4
1.7
V
0.35
1.00
V
VCIS, CFM
RSL clock input swing : VCIS = VCIH – VCIL (CFM, CFMN pins).
0.225
1.00
V
VIL, CMOS
CMOS input low voltage
– 0.3
+ (VCMOS / 2– 0.25)
V
VIH, CMOS
CMOS input high voltage
VCMOS / 2+0.25
VCMOS + 0.3
V
Data Sheet E0251N20 (Ver. 2.0)
55
µPD488588FF-C80-40
27. Timing Conditions
Timing Conditions
Symbol
Parameter
tCYCLE
CTM and CFM cycle times
tCR, tCF
CTM and CFM input rise and fall times
tCH, tCL
CTM and CFM high and low times
tTR
CTM-CFM differential
Unit
Figures
3.83
ns
Figure 30-1
0.5
ns
Figure 30-1
40%
60%
tCYCLE
Figure 30-1
(MSE/MS=0/0)
0.0
1.0
tCYCLE
Figure 22-1
(MSE/MS=1/1) Note1
0.9
1.0
-C80
MIN.
MAX.
2.50
0.2
Figure 30-1
tDCW
Domain crossing window
–0.1
+0.1
tCYCLE
Figure 35-1
tDR, tDF
DQA/DQB/ROW/COL input rise/fall times
0.2
0.65
ns
Figure 31-1
tS, tH
DQA/DQB/ROW/COL-to-CFM
0.200
—
ns
Figure 31-1
tCYCLE=2.50ns
setup/hold time
tDR1, tDF1
SIO0, SIO1 input rise and fall times
—
5.0
ns
Figure 33-1
tDR2, tDF2
CMD,SCK input rise and fall times
—
2.0
ns
Figure 33-1
tCYCLE1
SCK cycle time - Serial control register transactions
1,000
—
ns
Figure 33-1
10
—
ns
Figure 33-1
4.25
—
ns
Figure 33-1
1.25
—
ns
Figure 33-1
1
—
ns
Figure 33-1
SCK cycle time - Power transitions
tCH1, tCL1
SCK high and low times
Note2
tS1
CMD setup time to SCK rising or falling edge
tH1
CMD hold time to SCK rising or falling edge Note2
tS2
SIO0 setup time to SCK falling edge
40
—
ns
Figure 33-1
tH2
SIO0 hold time to SCK falling edge
40
—
ns
Figure 33-1
tS3
PDEV setup time on DQA5..0 to SCK rising edge
0
—
ns
Figure 23-4, 33-2
tH3
PDEV hold time on DQA5..0 to SCK rising edge
5.5
—
ns
Figure 23-4, 33-2
tS4
ROW2..0, COL4..0 setup time for quiet window Note3
–1
—
tCYCLE
Figure 23-4
tH4
ROW2..0, COL4..0 hold time for quiet window
Figure 23-4
VIL, CMOS
CMOS input low voltage - over / undershoot voltage
VIH, CMOS
CMOS input high voltage - over / undershoot voltage
5
—
tCYCLE
–0.7
+(VCMOS/2–0.6)
V
VCMOS/2 + 0.6
VCMOS + 0.7
V
duration is less than or equal to 5 ns
duration is less than or equal to 5ns
tNPQ
Quiet on ROW / COL bits during NAP / PDN entry
4
—
tCYCLE
Figure 23-3
tREADTOCC
Offset between read data and CC packets (same device)
12
—
tCYCLE
Figure 25-1
tCCSAMTOREAD Offset between CC packet and read data (same device)
8
—
tCYCLE
Figure 25-1
tCE
CTM/CFM stable before NAP/PDN exit
2
—
tCYCLE
Figure 23-4
tCD
CTM/CFM stable after NAP/PDN entry
100
—
tCYCLE
Figure 23-3
tFRM
ROW packet to COL packet ATTN framing delay
7
—
tCYCLE
Figure 23-2
tNLIMIT
Maximum time in NAP mode
—
10
µs
Figure 23-1
tREF
Refresh interval
tCCTRL
Current control interval
tTEMP
Temperature control interval
tTCEN
TCE command to TCAL command
tTCAL
TCAL command to quiet window
tTCQUIET
Quiet window (no read data)
tPAUSE
tBURST
56
—
32
ms
Figure 24-1
34 tCYCLE
100 ms
—
Figure 25-1
—
100
ms
Figure 25-2
150
—
tCYCLE
Figure 25-2
2
2
tCYCLE
Figure 25-2
140
—
tCYCLE
Figure 25-2
RDRAM delay (no RSL operations allowed)
—
200
µs
Figure 22-1
Interval after PDN or NAP (with self-refresh) exit in which
all banks of the RDRAM must be refreshed at least once.
—
200
µs
Figure 24-2
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Notes 1. MSE/MS are fields of the SKIP register. For this combination (skip override) the tDCW parameter range is
effectively 0.0 to 0.0.
2. With VIL,CMOS = 0.5 VCMOS − 0.6 V and VIH,CMOS = 0.5 VCMOS + 0.6 V
3. Effective hold becomes tH4’=tH4 + [PDNXA • 64 • tSCYCLE + tPDNXB,MAX ] − [PDNX • 256 • tSCYCLE ]
if [PDNX • 256 • tSCYCLE ] < [PDNXA • 64 • tSCYCLE + tPDNXB,MAX ]. See Figure 23-4.
Data Sheet E0251N20 (Ver. 2.0)
57
µPD488588FF-C80-40
28. Electrical Characteristics
Electrical Characteristics
Symbol
Parameter and Conditions
ΘJC
Junction-to-Case thermal resistance
MIN.
MAX.
Unit
—
0.5
°C/Watt
IREF
VREF current @ VREF,MAX
–10
+10
µA
IOH
RSL output high current @ (0≤VOUT ≤VDD)
–10
+10
µA
IALL
RSL IOL current @ VOL=0.9 V, VDD,MIN, Tj,MAX Note
30
90
mA
∆IOL
RSL IOL current resolution step
rOUT
Dynamic output impedance
II,CMOS
CMOS input leakage current @ (0 ≤ VI,CMOS ≤ VCMOS)
VOL,CMOS
CMOS output low voltage @ IOL,CMOS = 1.0 mA
VOH,CMOS
CMOS output high voltage @ IOH,CMOS = – 0.25 mA
—
2.0
mA
150
—
Ω
–10.0
+10.0
µA
—
0.3
V
VCMOS – 0.3
—
V
Note This measurement is made in manual current control mode; i.e. with all output device legs sinking current.
29. Timing Characteristics
Timing Characteristics
Symbol
Parameter
Unit
Figure(s)
tQ
CTM-to-DQA/DQB output time
tQR, tQF
DQA/DQB output rise and fall times
+0.260
ns
Figure 32-1
0.45
ns
Figure 32-1
tQ1
—
10
ns
Figure 34-1
tHR
SCK(pos)-to-SIO0 delay @ CLOAD,MAX = 20pF (SD read data hold)
2
—
ns
Figure 34-1
tQR1, tQF1
SIOOUT rise/fall @ CLOAD,MAX = 20 pF
—
5
ns
Figure 34-1
tPROP1
SIO0-to-SIO1 or SIO1-to-SIO0 delay @ CLOAD,MAX = 20 pF
—
10
ns
Figure 34-1
tNAPXA
NAP exit delay - phase A
—
50
ns
Figure 23-4
tNAPXB
NAP exit delay - phase B
—
40
ns
Figure 23-4
tPDNXA
PDN exit delay - phase A
—
4
µs
Figure 23-4
tPDNXB
PDN exit delay - phase B
—
9,000
tCYCLE
Figure 23-4
tAS
ATTN-to-STBY power state delay
—
1
tCYCLE
Figure 23-2
tSA
STBY-to-ATTN power state delay
—
0
tCYCLE
Figure 23-2
tASN
ATTN/STBY-to-NAP power state delay
—
8
tCYCLE
Figure 23-3
tASP
ATTN/STBY-to-PDN power state delay
—
8
tCYCLE
Figure 23-3
58
MIN.
MAX.
–0.260
0.2
SCK-to-SIO0 delay @ CLOAD,MAX = 20 pF (SD read packet)
tCYCLE = 2.50 ns
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
30. RSL Clocking
Figure 30-1 is a timing diagram which shows the detailed requirements for the RSL clock signals on the Channel.
The CTM and CTMN are differential clock inputs used for transmitting information on the DQA and DQB, outputs.
Most timing is measured relative to the points where they cross. The tCYCLE parameter is measured from the falling
CTM edge to the falling CTM edge. The tCL and tCH parameters are measured from falling to rising and rising to falling
edges of CTM. The tCR and tCF rise-and fall-time parameters are measured at the 20 % and 80 % points.
The CFM and CFMN are differential clock outputs used for receiving information on the DQA, DQB, ROW and COL
outputs. Most timing is measured relative to the points where they cross. The tCYCLE parameter is measured from the
falling CFM edge to the falling CFM edge. The tCL and tCH parameters are measured from falling to rising and rising to
falling edges of CFM. The tCR and tCF rise- and fall-time parameters are measured at the 20 % and 80 % points. The
tTR parameters specifies the phase difference that may be tolerated with respect to the CTM and CFM differential
clock inputs (the CTM pair is always earlier).
Figure 30-1 RSL Timing - Clock Signals
t CYCLE
t CL
t CH
t CR
t CR
CTM
V CIH
80%
VXVCM
50%
VX+
20%
V CIL
t CF
CTMN
t CF
t TR
t CR
tCR
CFM
V CIH
80%
VXVCM
VX+
50%
20%
V CIL
CFMN
t CL
t CH
t CF
t CF
t CYCLE
Data Sheet E0251N20 (Ver. 2.0)
59
µPD488588FF-C80-40
31. RSL - Receive Timing
Figure 31-1 is a timing diagram which shows the detailed requirements for the RSL input signals on the Channel.
The DQA, DQB, ROW, and COL signals are inputs which receive information transmitted by a Direct RAC on the
Channel. Each signal is sampled twice per tCYCLE interval. The set/hold window of the sample points is tS/tH. The
sample points are centered at the 0 % and 50 % points of a cycle, measured relative to the crossing points of the
falling CFM clock edge. The set and hold parameters are measured at the VREF voltage point of the input transition.
The tDR and tDF rise- and fall-time parameters are measured at the 20 % and 80 % points of the input transition.
Figure 31-1 RSL Timing - Data Signals for Receive
CFM
V CIH
80%
VXVCM
50%
VX+
20%
V CIL
CFMN
0.5•t CYCLE
DQA
DQB
tS
t DR
tH
tS
tH
V DIH
ROW
80%
COL
even
odd
V REF
20%
VDIL
t DF
60
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
32. RSL - Transmit Timing
Figure 32-1 is a timing diagram which shows the detailed requirements for the RSL output signals on the Channel.
The DQA and DQB signals are outputs to transmit information that is received by a Direct RAC on the Channel.
Each signal is driven twice per tCYCLE interval. The beginning and end of the even transmit window is at the 75 %
point of the previous cycle and at the 25 % point of the current cycle. The beginning and end of the odd transmit
window is at the 25 % point and at the 75 % point of the current cycle. These transmit points are measured relative to
the crossing points of the falling CTM clock edge. The size of the actual transmit window is less than the ideal
tCYCLE/2, as indicated by the non-zero valued of tQ,MIN and tQ,MAX. The tQ parameters are measured at the 50 % voltage
point of the output transition.
The tQR and tQF rise- and fall-time parameters are measured at the 20 % and 80 % points of the output transition.
Figure 32-1 RSL Timing - Data Signals for Transmit
CTM
VCIH
80%
VXVCM
50%
VX+
20%
CTMN
VCIL
0.75•t CYCLE
0.75•t CYCLE
0.25•t CYCLE
DQA
DQB
tQ,MIN
t Q,MIN t Q,MAX
tQ,MAX
tQR
VQH
80%
even
odd
50%
20%
t QF
Data Sheet E0251N20 (Ver. 2.0)
VQL
61
µPD488588FF-C80-40
33. CMOS - Receive Timing
Figure 33-1 is a timing diagram which shows the detailed requirements for the CMOS input signals.
The CMD and SIO0 signals are inputs which receive information transmitted by a controller (or by another RDRAM’s
SIO1 output). SCK is the CMOS clock signal driven by the controller. All signals are high true.
The cycle time, high phase time, and low phase time of the SCK clock are tCYCLE1, tCH1 and tCL1, all measured at the
50 % level. The rise and fall times of SCK, CMD, and SIO0 are tDR1 and tDF1, measured at the 20 % and 80 % levels.
The CMD signal is sampled twice per tCYCLE1 interval, on the rising edge (odd data) and the falling edge (even data).
The set/hold window of the sample points is tS1/tH1. The SCK and CMD timing points are measured at the 50 % level.
The SIO0 signal is sampled once per tCYCLE1 interval on the falling edge. The set/hold window of the sample points
is tS2/tH2. The SCK and SIO0 timing points are measured at the 50 % level.
Figure 33-1 CMOS Timing - Data Signals for Receive
t DR2
V IH,CMOS
SCK
80%
50%
20%
t CYCLE1
t DF2
t CH1
t S1
tDR2
V IL,CMOS
t CL1
tH1
tS1
t H1
V IH,CMOS
CMD
80%
even
odd
50%
20%
VIL,CMOS
t DF2
t DR1
tS2
t H2
V IH,CMOS
SIO0
80%
50%
20%
V IL,CMOS
t DF1
62
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
The SCK clock is also used for sampling data on RSL input in one situation. Figure23-4 shows the PDN and NAP
exit sequences. If the PSX field of the INIT register is one (Figure 22-1 control registers (1/7) “INIT Register”), then
the PDN and NAP exit sequences are broadcast; i.e. all RDRAMs that are in PDN or NAP will perform the exit
sequence. If the PSX field of the INIT register is zero, then the PDN and NAP exit sequences are directed; i.e. only
one RDRAM that is in PDN or NAP will perform the exit sequence.
The address of that RDRAM is specified on the DQA[5:0] bus in the set hold window tS3/tH3 around the rising edge of
SCK. This is shown Figure 33-2. The SCK timing point is measured at the 50 % level, and the DQA [5:0] bus signals
are measured at the VREF level.
Figure 33-2 CMOS Timing - Device Address for NAP or PDN Exit
V IH,CMOS
SCK
80%
50%
20%
V IL,CMOS
t S3
t H3
V DIH
DQA[5:0]
80%
PDEV
V REF
20%
VDIL
Data Sheet E0251N20 (Ver. 2.0)
63
µPD488588FF-C80-40
34. CMOS - Transmit Timing
Figure 34-1 is a timing diagram which shows the detailed requirements for the CMOS output signals. The SIO0
signal is driven once per tCYCLE1 interval on the falling edge. The clock-to-output window is tQ1,MIN /tQ1,MAX. The SCK
and SIO0 timing points are measured at the 50 % level. The rise and fall times of SIO0 are tQR1 and tQF1, measured at
the 20 % and 80 % levels.
Figure34-1 also shows the combinational path connecting SIO0 to SIO1 and the path connecting SIO1 to SIO0
(read data only). The tPROP1 parameter specified this propagation delay. The rise and fall times of SIO0 and SIO1
input must be tDR1 and tDF1, measured at the 20 % and 80 % levels. The rise and fall times of SIO0 and SIO1 outputs
are tQR1 and tQF1, measured at the 20 % and 80 % levels.
Figure 34-1 CMOS Timing - Data Signals for Transmit
VIH,CMOS
SCK
80%
50%
20%
VIL,CMOS
t HR,MIN
t Q1,MAX
t QR1
VOH,CMOS
SIO0
80%
50%
20%
VOL,CMOS
t QF1
t DR1
VIH,CMOS
SIO0
or
SIO1
80%
50%
20%
VIL,CMOS
t DF1
t PROP1,MAX
t PROP1,MIN
tQR1
VOH,CMOS
SIO0
or
SIO1
80%
50%
20%
VOL,CMOS
t QF1
64
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
35. RSL - Domain Crossing Window
When read data is returned by the RDRAM, information must cross from the receive clock domain (CFM) to the
transmit clock domain (CTM). The tTR parameter permits the CFM to CTM phase to vary though an entire cycle ; i.e.
there is no restriction on the alignment of these two clocks. A second parameter tDCW is needed in order to describe
how the delay between a RD command packet and read data packet varies as a function of the tTR value.
Figure 35-1 shows this timing for five distinct values of tTR. Case A (tTR=0) is what has been used throughout this
document. The delay between the RD command and read data is tCAC. As tTR varies from zero to tCYCLE (cases A
through E), the command to data delay is (tCAC-tTR). When the tTR value is in the range 0 to tDCW,MAX, the command to
data delay can also be (tCAC-tTR-tCYCLE). This is shown as cases A’ and B’ (the gray packets). Similarly, when the tTR
value is in the range (tCYCLE+tDCW,MIN) to tCYCLE, the command to data delay can also be (tCAC-tTR+tCYCLE). This is shown
as cases D’ and E’ (the gray packets). The RDRAM will work reliably with either the white or gray packet timing. The
delay value is selected at initialization, and remains fixed thereafter.
Figure 35-1 RSL Timing - Crossing Read Domains
CFM
•••
COL
•••
CTM
DQA/B
t CYCLE
RDa1
tTR
Case A
tCAC -t TR
t TR=0
Q(a1)
t CAC -tTR-tCYCLE
Case A' t TR=0
DQA/B
Q(a1)
•••
CTM
tTR
DQA/B
Case B t TR =t DCW,MAX
DQA/B
Case B' t TR =t DCW,MAX
tTR
t TR
Q(a1)
Case D
tTR =t CYCLE + t DCW,MIN
t CAC -tTR
Case D'
t TR =t CYCLE + t DCW,MIN
tCAC -t TR +t CYCLE
Q(a1)
Q(a1)
•••
CTM
t TR
DQA/B
t CAC -t TR
Case C t TR =0.5•t CYCLE
•••
DQA/B
DQA/B
Q(a1)
•••
CTM
DQA/B
Q(a1)
t CAC -t TR -t CYCLE
CTM
DQA/B
t CAC -t TR
t CAC -t TR
Case E t TR =t CYCLE
Case E' t TR =t CYCLE
Q(a1)
t CAC -tTR+tCYCLE
Q(a1)
Data Sheet E0251N20 (Ver. 2.0)
65
µPD488588FF-C80-40
36. Timing Parameters
Timing Parameters Summary
Para-
Description
-C80
meter
Units
Figures
-40
MIN.
MAX.
Row Cycle time of RDRAM banks - the interval between ROWA packets
with ACT commands to the same bank.
28
—
RAS-asserted time of RDRAM bank - the interval between ROWA packet
with ACT command and next ROWR packet with PRER Note 1 command to the
same bank.
20
Row Precharge time of RDRAM banks - the interval between ROWR packet
with PRER Note 1 command and next ROWA packet with ACT command to the
same bank.
8
tPP
Precharge-to-precharge time of RDRAM device - the interval between
successive ROWR packets with PRER Note 1 commands to any banks of
the same device.
8
—
tCYCLE Figure10-3
tRR
RAS-to-RAS time of RDRAM device - the interval between successive
ROWA packets with ACT commands to any banks of the same device.
8
—
tCYCLE Figure12-1
tRCD
RAS-to-CAS Delay - the interval from ROWA packet with ACT
command to COLC packet with RD or WR command. Note - the RASto-CAS delay seen by the RDRAM core (tRCD-C) is equal to tRCD-C = 1 +
tRCD because of differences in the row and column paths through the
RDRAM interface.
7
—
tCYCLE Figure13-1
CAS Access delay - the interval from RD command to Q read data. The
equation for tCAC is given in the TPARM register in Figure 22-1(5/7).
8
tRC
tRAS
tRP
tCAC
tCYCLE Figure13-1
Figure14-1
Note 2
tCYCLE Figure13-1
64µs
—
Figure14-1
tCYCLE Figure13-1
Figure14-1
Figure14-1
12
tCYCLE
Figure4-1
Figure4-1
tCWD
CAS Write Delay - interval from WR command to D write data.
6
6
tCYCLE
tCC
CAS-to-CAS time of RDRAM bank - the interval between successive
COLC commands.
4
—
tCYCLE Figure13-1
tPACKET
Length of ROWA, ROWR, COLC, COLM or COLX packet.
4
4
tCYCLE
tRTR
Interval from COLC packet with WR command to COLC packet which
causes retire, and to COLM packet with bytemask.
8
—
tCYCLE Figure15-1
tOFFP
The interval (offset) from COLC packet with RDA command, or from
COLC packet with retire command (after WRA automatic precharge), or
from COLC packet with PREC command, or from COLX packet with
PREX command to the equivalent ROWR packet with PRER. The
equation for tOFFP is given in the TPARM register in Figure 22-1(5/7).
4
4
tCYCLE Figure14-2
tRDP
Interval from last COLC packet with RD command to ROWR packet
with PRER.
4
—
tCYCLE Figure13-1
tRTP
Interval from last COLC packet with automatic retire command to
ROWR packet with PRER.
4
—
tCYCLE Figure14-1
Figure14-1
Figure2-1
Notes 1. Or equivalent PREC or PREX command. See Figure 12-2.
2. This is a constraint imposed by the core, and is therefore in units of ms rather than tCYCLE.
66
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
37. Absolute Maximum Ratings
Absolute Maximum Ratings
Symbol
Parameter
MIN.
MAX.
Unit
VI,ABS
Voltage applied to any RSL or CMOS pin with respect to GND
–0.3
VDD +0.3
V
VDD,ABS ,VDDa,ABS
Voltage on VDD and VDDa with respect to GND
–0.5
VDD +1.0
V
TSTORE
Storage temperature
–50
+100
°C
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.
38. IDD - Supply Current Profile
IDD - Supply Current Profile
IDD value
RDRAM blocks consuming power
@ tCYCLE Note 1
MIN.
MAX.
Unit
IDD,PDN
Self-refresh only for INIT.LSR=0

6.0
mA
IDD,NAP
T/RCLK-Nap

4.2
mA
IDD,STBY
T/RCLK,ROW-demux

90
mA
2.50 ns
IDD,ATTN
T/RCLK, ROW-demux, COL-demux
2.50 ns

135
mA
IDD,ATTN-W
T/RCLK, ROW-demux, COL-demux,
2.50 ns

765
mA
2.50 ns

705
mA
DQ-demux, 1•WR-SenseAmp, 4•ACT-Bank
IDD,ATTN-R
T/RCLK, ROW-demux, COL-demux,
DQ-mux, 1•RD-SenseAmp, 4•ACT-Bank Note 2
Notes 1. The CMOS interface consumes power in all power states.
2. This does not include the IOL sink current. The RDRAM dissipates IOL•VOL in each output driver when a logic
one is driven.
Data Sheet E0251N20 (Ver. 2.0)
67
µPD488588FF-C80-40
39. Capacitance and Inductance
Figure 39-1 shows the equivalent load circuit of the RSL and CMOS pins. The circuit models the load that the
device presents to the Channel.
This circuit does not include pin coupling effects that are often present in the packaged device. Because coupling
effects make the effective single-pin inductance LI, and capacitance CI, a function of neighboring pins, these
parameters are intrinsically data-dependent. For purposes of specifying the device electrical loading on the Channel,
the effective LI and CI are defined as the worst-case values over all specified operating conditions.
LI is defined as the effective pin inductance based on the device pin assignment. Because the pad assignment
places each RSL signal adjacent to an AC ground (a GND or VDD pin), the effective inductance must be defined
based on this configuration. Therefore, LI assumes a loop with the RSL pin adjacent to an AC ground.
CI is defined as the effective pin capacitance based on the device pin assignment. It is the sum of the effective
package pin capacitance and the IO pad capacitance.
Figure 39-1 Equivalent Load Circuit for RSL Pins
Pad
LI
DQA,DQB,RQ Pin
CI
RI
GND Pin
Pad
LI
CTM,CTMN,
CFM,CFMN Pin
CI
RI
GND Pin
Pad
L I,CMOS
SCK,CMD Pin
CI
GND Pin
Pad
L I,CMOS
SIO0,SIO1 Pin
C I,CMOS,SIO
GND Pin
68
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
RSL Pin Parasitics
Symbol
Parameter and Conditions - RSL pins
MIN.
MAX.
Unit
LI
RSL effective input inductance
–
4.0
nH
L12
Mutual inductance between any DQA or DQB RSL signals.
–
0.2
nH
Mutual inductance between any ROW or COL RSL signals.
–
0.6
nH
∆LI
Difference in LI value between any RSL pins of a single device.
CI
RSL effective input capacitance
C12
–
1.8
nH
2.0
2.4
pF
Mutual capacitance between any RSL signals.
–
0.1
pF
∆CI
Difference in CI value between any RSL pins of a single device.
–
0.06
pF
RI
RSL effective input resistance
4
15
Ω
MIN.
MAX.
Unit
–
8.0
nH
1.7
2.1
pF
–
7.0
pF
Note
800 MHz
Note This value is a combination of the device IO circuitry and package capacitances.
CMOS Pin Parasitics
Symbol
Parameter and Conditions - CMOS pins
LI,CMOS
CMOS effective input inductance
CI,CMOS
CI,CMOS,SIO
CMOS effective input capacitance (SCK,CMD)
CMOS effective input capacitance (SIO1,SIO0)
Note
Note
Note This value is a combination of the device IO circuitry and package capacitances.
Data Sheet E0251N20 (Ver. 2.0)
69
µPD488588FF-C80-40
40. Interleaved Device Mode
Interleaved Device Mode permits a group of eight RDRAMs on the Channel to collectively respond to acommand.
The purpose of this collective response is to limit the number of bits in each dualoct data packet which are read from
or written to a single RDRAM device. This capability permits a memory controller to implement hardware for fault
detection and correction that can tolerate the complete internal failure of one RDRAM device on a Channel.
The IDM bit of the INIT control register enables this fault tolerant operating mode. When it is set, the RDRAM will
interpret the DR4..0 and DC4..0 fields of the ROW and COLC packets differently. Figure 40-1 shows the differences
using an example system with eight RDRAMs.
The DEVID4..0 registers of these RDRAMs are initial-ized to “00000” through “00111’. However, when the IDM bit is
set, only the upper two bits (DEVID4..3) will be compared to the DR4..3 and DC4..3 fields. This means that ROW and
COLC packets will be executed by groups of eight RDRAMs, with a Channel containing from one to four of these
groups. The low-order DR2..0 bits are not used when IDM is set, and the low-order DC2..0 bits have a modified
function described below.
With IDM set, a directed ACT or PRE command in a ROW packet causes eight RDRAMs to perform the indicated
operation. Likewise, when a RD or WR command is specified in a COLC command, the selected group of eight
RDRAMs responds. When using IDM, devices must be added to the Channel in groups of eight. An application will
typically make the IDM bit setting the same for all RDRAMs on a Channel.
The mechanism for indicating a broadcast ROW packet (DR4F and DR4T are both set to one) is not affected by the
setting of the IDM bit; i.e. IDM mode does not change the broadcast ROW packet mechanism.
Likewise, the COLX fields (DX4..0, XOP4..0, and BX5..0) are not changed by IDM mode - all COLX packets are
directed to a single device.
When the IDM bit is set, COLM packets should not be used (the M bit should be set to zero, selecting only COLX
packets). This is because the mapping of bytes to RDRAM storage cells is changed by IDM mode.
Returning to Figure 40-1, the remaining fields of the ROW and COLC packets are interpreted in the same way
regardless of the setting of the IDM bit – IDM mode does not affect these fields. Specifically, the BR5..0 and BC5..0
fields of the ROW and COLC packets are used to select one of the banks just as when IDM is not set. The R8..0 field
of the ROW packet selects a row of the selected (BR5..0) bank to load into the bank’s sense amp. And the C6..0 field
selects one dualoct of the selected (BC5..0) bank’s sense amp.
The IDM bit affects what is done with this selected dualoct. When IDM is not set, the dualoct is driven onto the
Channel by the single selected RDRAM device. When IDM is set, the RDRAM of the eight device group selected by
DC4..3 drives 16 or 24 bits (x18 device) of the 144-bit dualoct. The bits driven are a function of the DEVID2..0
RDRAM register field, the DC2..0 COLC packet field, and the device width (x18). Figure 40-1 shows the mapping that
is appropriate for DC2..0=000.
Figure 40-2 and Figure 40-3 show the mapping for all eight values of DC2..0. There are eight mappings, which are
rotated among the eight devices using the following equation:
Pin = 7 - 4 • (DEVID2^DC2)
- 2 • (DEVID1^DC1) - 1 • (DEVID0^DC0) (Eq 1)
where “^” is the exclusive-or function. “Pin” is the pin number that is driven by the RDRAM with the DEVID2..0 value.
For example, Pin=0 means the RDRAM drives DQA0 and DQB0, and so forth. The DQA8 pin is always driven with
DQA7, and DQB8 is always driven with DQB6 for x18 devices. For x16 devices, the DQA8 and DQB8 pins are not
used. For each of the eight mappings, the eight-RDRAM group supplies a complete dualoct. As the application steps
through eight values of DC2..0, all the bits of the eight underlying dualocts will be accessed. Thus, an eight-RDRAM
group appears to be a single RDRAM with eight times the normal page size, with the DC2..0 field providing the extra
column addressing informa-tion (beyond what C6..0 provides).
70
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
Figure 40-1 ACT, PRE, RD, and WR Commands for Eight RDRAM System with IDM = 1
RDRAM 0
RDRAM 1
RDRAM 2
RDRAM 3
RDRAM 4
RDRAM 5
RDRAM 6
RDRAM 7
DEVID
4..0
00000
00001
00010
00011
00100
00101
00110
00111
DR4..3
DC4..3
compare to
DEVID4..3
same as
device 0
same as
device 0
same as
device 0
same as
device 0
same as
device 0
same as
device 0
same as
device 0
DQA6
DQB6
DQB8
DQA5
DQB5
DQA4
DQB4
DQA3
DQB3
DQA2
DQB2
DQA1
DQB1
DQA0
DQB0
access
device
bank array
•
BR5..0
BC5..0
•
•
access
bank
•
one bank
• •
R12..0
•
• •
access
row
•
• •
PRE
ACT
sense
amp.
C6..0
• •
• •
access
column
WR
RD
DC2..0
=000
form
dualoct
DQA7
DQB7
DQA8
Channel
notation
DQA0
• •
•
DQA8
DQB0
•
•
• •
•
•
•
•
DQB8
CTM/CFM
•
• •
B
device (2 banks)
R
bank (2 rows)
Data Sheet E0251N20 (Ver. 2.0)
• •
row (2C dualocts)
dualoct (144 bits)
one bit
71
µPD488588FF-C80-40
Figure 40-2 Mapping from DEVID2..0 and DC2..0 Fields to DQ Packet with IDM = 1
DEVID2..0
000
001
010
011
100
101
110
111
DC2..0
Mapping for
previous figure
000
DQA7
DQB7
DQA8
DQA6
DQB6
DQB8
DQA5
DQB5
DQA4
DQB4
DQA3
DQB3
DQA2
DQB2
DQA1
DQB1
DQA0
DQB0
001
CTM/CFM
DQA6
DQB6
DQB8
DQA7
DQB7
DQA8
DQA4
DQB4
DQA5
DQB5
DQA2
DQB2
DQA3
DQB3
DQA0
DQB0
DQA1
DQB1
DQA5
DQB5
DQA4
DQB4
DQA7
DQB7
DQA8
DQA6
DQB6
DQB8
DQA1
DQB1
DQA0
DQB0
DQA3
DQB3
DQA2
DQB2
DQA4
DQB4
DQA5
DQB5
DQA6
DQB6
DQB8
DQA7
DQB7
DQA8
DQA0
DQB0
DQA1
DQB1
DQA2
DQB2
DQA3
DQB3
010
011
72
Data Sheet E0251N20 (Ver. 2.0)
DQA0
DQA1
DQA2
DQA3
DQA4
DQA5
DQA6
DQA7
DQA8
DQB0
DQB1
DQB2
DQB3
DQB4
DQB5
DQB6
DQB7
DQB8
µPD488588FF-C80-40
Figure 40-3 Mapping from DEVID2..0 and DC2..0 Fields to DQ Packet with IDM = 1 (continued)
DEVID2..0
000
001
010
011
100
101
110
111
DQA3
DQB3
DQA2
DQB2
DQA1
DQB1
DQA0
DQB0
DQA7
DQB7
DQA8
DQA6
DQB6
DQB8
DQA5
DQB5
DQA4
DQB4
DC2..0
100
101
CTM/CFM
DQA2
DQB2
DQA3
DQB3
DQA0
DQB0
DQA1
DQB1
DQA6
DQB6
DQB8
DQA7
DQB7
DQA8
DQA4
DQB4
DQA5
DQB5
DQA1
DQB1
DQA0
DQB0
DQA3
DQB3
DQA2
DQB2
DQA5
DQB5
DQA4
DQB4
DQA7
DQB7
DQA8
DQA6
DQB6
DQB8
DQA0
DQB0
DQA1
DQB1
DQA2
DQB2
DQA3
DQB3
DQA4
DQB4
DQA5
DQB5
DQA6
DQB6
DQB8
DQA7
DQB7
DQA8
110
DQA0
DQA1
DQA2
DQA3
DQA4
DQA5
DQA6
DQA7
DQA8
DQB0
DQB1
DQB2
DQB3
DQB4
DQB5
DQB6
DQB7
DQB8
111
Data Sheet E0251N20 (Ver. 2.0)
73
µPD488588FF-C80-40
41. Glossary of Terms
ACT
Activate command from AV field.
D
Write data packet on DQ pins.
activate
To access a roe and place in sense amp.
DBL
CNFGB register field – doubled-bank.
activate
To access a row and place in sense amp.
DC
Device address field in COLC packet.
adjacent
Two RDRAM banks which share sense amps
(also called doubled banks).
device
An RDRAM on a Channel.
DEVID
Control register with device address that is
matched against DR, DC, and DX fields.
ASYM
CCA register field for RSL VOL / VOH.
ATTN
Power state – ready for ROW / COL packets.
DM
Device match for ROW packet decode.
ATTNR
Power state – transmitting Q packets.
Doubled-bank
RDRAM with shared sense amp.
ATTNW
Power state – receiving D packets.
DQ
DQA and DQB pins.
AV
Opcode field in ROW packets.
DQA
Pins for data byte A.
bank
A block of 2RBIT•2CBIT storage cells in the core
of the RDRAM.
DQB
Pins for data byte B.
DQS
NAPX register field – PDN/NAP exit.
BC
Bank address field in CLC packet.
BBIT
CNFGA register field - # bank address bits.
DR,DR4T,DR4F Device address field and packet framing fields
in ROW and ROWE packets.
broadcast
An operation executed by all RDRAMs.
dualoct
16 bytes – the smallest addressable datum.
BR
Bank address field in ROW packets.
DX
Device address field in COLX packet.
bubble
Idle cycle(s) on RDRAM pins needed
because of a resource constraint.
field
A collection of bits in a packet.
INIT
Control register with initialization fields.
BYT
CNFGB register field – 9 bits per byte.
initialization
BX
Bank address field in COLX packet.
Configuring a Channel of RDRAMs so they
are ready to respond to transactions.
C
Column address field in COLC packet.
LSR
CNFGA register field – low-power self-refresh.
CAL
Calibrate (IOL) command in XOP field.
M
Mask opcode field (COLM/COLX packet).
CBIT
CNFGB register field - # column address bits.
MA
Field in COLM packet for masking byte A.
CCA
Control register – current control A.
MB
Field in COLM packet for masking byte B.
CCB
Control register – current control B.
MSK
Mask command in M field.
CFM,CFMN
Clock pins for receiving packets.
MVER
Control register – manufacturer ID.
Channel
ROW / COL / DQ pins and external wires.
NAP
Power state – needs SCK/CMD wakeup.
CLRR
Clear reset command from SOP field.
NAPR
Nap command in ROP field.
CMD
CMOS pins for initialization / power control.
NAPRC
Conditional nap command in ROP field.
CNFGA
Control register with configuration fields.
NAPXA
NAPX register field – NAP exit delay A.
CNFGB
Control register with configuration fields.
NAPXB
NAPX register field – NAP exit delay B.
COL
Pins for column-access control.
NOCOP
No-operation command in COP field.
COLC
Column operation packet on COL pins.
NOROP
No-operation command in ROP field.
COLM
Write mask packet on COL pins.
NOXOP
No-operation command in XOP field.
column
Rows in a bank or activated in sense amps
have 2CBTI dualocts column storage.
NSR
INIT register field – NAP self-refresh.
packet
A collection of bits carried on the Channel.
Command
A decoded bit-combination from a field.
PDN
Power state – needs SCK/CMD wakeup.
COLX
Extended operation packet on COL pins.
PDNR
Powerdown command in ROP field.
controller
A logic-device which drives the ROW / COL
/ DQ wires for a Channel of RDRAMs.
PDNXA
Control register – PDN exit delay A.
PDNXB
Control register – PDN exit delay B.
COP
Column opcode field in COLC packet.
pin efficiency
The fraction of non-idle cycles on a pin.
core
The banks and sense amps of an RDRAM.
PRE
PREC, PRER, PREX precharge commands.
CTM, CTMN
Clock pins for transmitting packets.
PREC
Precharge command in COP field.
Current control
Periodic operations to update the proper IOL
Value of RSL output drivers.
precharge
Prepares sense amp and bank for activate.
PRER
Precharge command in ROP field.
74
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
PREX
Precharge command in XOP field.
SETF
Set fast clock command from SOP field.
PSX
INIT register field – PDN/NAP exit.
SETR
Set reset command from SOP field.
SINT
Serial interval packet for control register
read/write transactions.
PSR
INIT register field – PDN self-refresh.
PVER
CNFGB register field – protocol version.
Q
Read data packet on DQ pins.
SIO0,SIO1
CMOS serial pins for control registers.
R
Row address field of ROWA packet.
SOP
Serial opcode field in SRQ.
RBIT
CNFGB register field - #row address bits.
SRD
Serial read opcode command from SOP.
RD/RDA
Read (/precharge) command in COP field.
SRP
INIT register field – Serial repeat bit.
read
Operation of accessing sense amp data.
SRQ
receive
Moving information from the Channel into the
RDRAM (a serial stream is demuxed).
Serial request packet for control register
read/write transactions.
STBY
Power state – ready for ROW packets.
REFA
Refresh-activate command in ROP field.
SVER
Control register – stepping version.
REFB
Control register – next bank (self-refresh).
SWR
Serial write opcode command from SOP.
REFBIT
CNFGA register field – ignore bank bits (for
REFA and self-refresh).
TCAS
TCLSCAS register field – tCAS core delay.
TCLS
TCLSCAS register field – tCLS core delay.
REFP
Refresh-precharge command in ROP field.
TCLSCAS
Control register – tCAS and tCLS delay.
REFR
Control register – next row for REFA.
TCYCLE
Control register – tCYCLE delay.
refresh
Periodic operations to restore storage cells.
TDAT
Control register – tDAC delay.
retire
The automatic operation that stores write
buffer into sense amp after WR command.
TEST77
Control register – for test purposes.
TEST78
Control register – for test purposes.
RLX
RLXC, RLXR, RLXX relax commands.
TRDLY
Control register – tRDLY delay.
RLXC
Relax command in COP field.
transaction
ROW, COL, DQ packets for memory access.
RLXR
Relax command in ROP field.
transmit
RLXX
Relax command in XOP field.
Moving information from the RDRAM onto
the Channel (parallel word is muxed).
ROP
Row-opcode field in ROWR packet.
WR/WRA
Write (/precharge) command in COP field.
row
2CBIT dualocts of cells (bank/sense amp).
write
Operation of modifying sense amp data.
ROW
Pins for row-access control
XOP
Extended opcode field in COLX packet.
ROW
ROWA or ROWR packets on ROW pins.
ROWA
Activate packet on ROW pins.
ROWR
Row operation packet on ROW pins.
RQ
Alternate name for ROW/COL pins.
RSL
Rambus Signal levels.
SAM
Sample (IOL) command in XOP field.
SA
Serial address packet for control register
transactions w/ SA address field.
SBC
Serial broadcast field in SRQ.
SCK
CMOS clock pin.
SD
Serial data packet for control register
transactions w/ SD data field.
SDEV
Serial device address in SRQ packet.
SDEVID
INIT register field – Serial device ID.
self-refresh
Refresh mode for PDN and NAP.
sense amp
Fast storage that holds copy of bank’s row.
Data Sheet E0251N20 (Ver. 2.0)
75
µPD488588FF-C80-40
42. Package Drawing
80-ball FBGA (µ BGA) (17.16 × 10.2)
E
w
S B
INDEX MARK
D
w
y1
S A
A
S
A1
S
y
S
b
φ x M
S A B
eE
SE
ITEM
ZE1
B
ZE2
ZD
U
T
S
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
eD
A
17.16±0.10
E
10.2±0.1
w
0.2
A
0.96±0.10
A1
eD
0.40±0.05
0.8
eE
b
0.8
0.50±0.05
x
SD
1 34
7 8 10
MILLIMETERS
D
0.08
y
0.1
y1
0.2
SD
0.4
SE
ZD
1.2
1.78
ZE1
1.1
ZE2
1.9
ECA-TS2-0051-02
76
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
43. Recommended Soldering Conditions
Please consult our sales office for soldering conditions of the µPD488588.
Type of Surface Mount Device
µ PD488588FF-DH1 : 80-ball FBGA (µ BGA) (17.16 × 10.2)
Data Sheet E0251N20 (Ver. 2.0)
77
µPD488588FF-C80-40
NOTES FOR CMOS DEVICES
1
PRECAUTION AGAINST ESD FOR MOS DEVICES
Exposing the MOS devices to a strong electric field can cause destruction of the gate
oxide and ultimately degrade the MOS devices operation. Steps must be taken to stop
generation of static electricity as much as possible, and quickly dissipate it, when once
it has occurred. Environmental control must be adequate. When it is dry, humidifier
should be used. It is recommended to avoid using insulators that easily build static
electricity. MOS devices must be stored and transported in an anti-static container,
static shielding bag or conductive material. All test and measurement tools including
work bench and floor should be grounded. The operator should be grounded using
wrist strap. MOS devices must not be touched with bare hands. Similar precautions
need to be taken for PW boards with semiconductor MOS devices on it.
2
HANDLING OF UNUSED INPUT PINS FOR CMOS DEVICES
No connection for CMOS devices input pins can be a cause of malfunction. If no
connection is provided to the input pins, it is possible that an internal input level may be
generated due to noise, etc., hence causing malfunction. CMOS devices behave
differently than Bipolar or NMOS devices. Input levels of CMOS devices must be fixed
high or low by using a pull-up or pull-down circuitry. Each unused pin should be connected
to VDD or GND with a resistor, if it is considered to have a possibility of being an output
pin. The unused pins must be handled in accordance with the related specifications.
3
STATUS BEFORE INITIALIZATION OF MOS DEVICES
Power-on does not necessarily define initial status of MOS devices. Production process
of MOS does not define the initial operation status of the device. Immediately after the
power source is turned ON, the MOS devices with reset function have not yet been
initialized. Hence, power-on does not guarantee output pin levels, I/O settings or
contents of registers. MOS devices are not initialized until the reset signal is received.
Reset operation must be executed immediately after power-on for MOS devices having
reset function.
CME0107
78
Data Sheet E0251N20 (Ver. 2.0)
µPD488588FF-C80-40
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Descriptions of circuits, software and other related information in this document are provided for
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incurred by customers or third parties arising from the use of these circuits, software and information.
[Product applications]
Elpida Memory, Inc. makes every attempt to ensure that its products are of high quality and reliability.
However, users are instructed to contact Elpida Memory's sales office before using the product in
aerospace, aeronautics, nuclear power, combustion control, transportation, traffic, safety equipment,
medical equipment for life support, or other such application in which especially high quality and
reliability is demanded or where its failure or malfunction may directly threaten human life or cause risk
of bodily injury.
[Product usage]
Design your application so that the product is used within the ranges and conditions guaranteed by
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characteristics, installation conditions and other related characteristics. Elpida Memory, Inc. bears no
responsibility for failure or damage when the product is used beyond the guaranteed ranges and
conditions. Even within the guaranteed ranges and conditions, consider normally foreseeable failure
rates or failure modes in semiconductor devices and employ systemic measures such as fail-safes, so
that the equipment incorporating Elpida Memory, Inc. products does not cause bodily injury, fire or other
consequential damage due to the operation of the Elpida Memory, Inc. product.
[Usage environment]
This product is not designed to be resistant to electromagnetic waves or radiation. This product must be
used in a non-condensing environment.
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compliance with the relevant laws and regulations.
M01E0107
Data Sheet E0251N20 (Ver. 2.0)