ETC UPD4616112F9-BC10-BC2

DATA SHEET
MOS INTEGRATED CIRCUIT
µPD4616112
16M-BIT CMOS MOBILE SPECIFIED RAM
1M-WORD BY 16-BIT
Description
The µPD4616112 is a high speed, low power, 16,777,216 bits (1,048,576 words by 16 bits) CMOS mobile specified
RAM featuring low power static RAM compatible function and pin configuration.
The µPD4616112 is fabricated with advanced CMOS technology using one-transistor memory cell.
The µPD4616112 is packed in 48-pin TAPE FBGA.
Features
• 1,048,576 words by 16 bits organization
• Fast access time: 80, 90, 100 ns (MAX.)
• Byte data control: /LB (I/O1 - I/O8), /UB (I/O9 - I/O16)
• Low voltage operation: VCC = 2.6 to 3.0 V
• Operating ambient temperature: TA = –20 to +70 °C
• Output Enable input for easy application
• Chip Enable input: /CS pin
• Standby Mode input: MODE pin
• Standby Mode1: Normal standby (Memory cell data hold valid)
• Standby Mode2: Memory cell data hold invalid
Product name
Access time
ns (MAX.)
µPD4616112-BCxx
80, 90, 100
Operating supply Operating ambient
Voltage
2.6 to 3.0
Supply current
temperature
At operating
At standby
°C
mA (MAX.)
µA (MAX.)
–20 to +70
35
100 / 10
The information in this document is subject to change without notice. Before using this document, please
confirm that this is the latest version.
Not all devices/types available in every country. Please check with local NEC representative for
availability and additional information.
Document No. M15085EJ4V0DS00
Date Published July 2001 NS CP (K)
Printed in Japan
The mark ★ shows major revised points.
©
2000
µPD4616112
★
Ordering Information
Part number
µPD4616112F9-BC80-BC2
★
Package
48-pin TAPE FBGA (6 x 8)
Access time
Operating
Operating
ns (MAX.)
supply voltage
temperature
V
°C
2.6 to 3.0
–20 to +70
80
µPD4616112F9-BC90-BC2
90
µPD4616112F9-BC10-BC2
100
Marking Image
Part number
Marking (XX)
µPD4616112F9-BC80-BC2
B1
µPD4616112F9-BC90-BC2
B2
µPD4616112F9-BC10-BC2
B3
J
MS16M0-XX
Index mark
2
Lot number
Data Sheet M15085EJ4V0DS
Remark
BC version
µPD4616112
Pin Configuration
/xxx indicates active low signal.
48-pin TAPE FBGA (6 x 8)
Top View
Bottom View
A
B
C
D
E
F
G
H
1
1
2
A
/LB
B
I/O9
C
I/O10
D
GND
E
F
G
H
2
3
4
3
4
/OE
A0
/UB
A3
I/O11
A5
I/O12
A17
VCC
I/O13
I/O15
I/O14
I/O16
A18
5
6
6
5
6
4
5
3
2
4
1
3
2
1
A1
A0
/OE
/LB
A4
A3
/UB
I/O9
A5
I/O11
I/O10
A17
I/O12
GND
5
6
A1
A2
MODE
A
MODE
A2
A4
/CS
I/O1
B
I/O1
/CS
A6
I/O2
I/O3
C
I/O3
I/O2
A6
A7
I/O4
VCC
D
VCC
I/O4
A7
GND
A16
I/O5
GND
E
GND
I/O5
A16
GND
I/O13
VCC
A14
A15
I/O6
I/O7
F
I/O7
I/O6
A15
A14
I/O14
I/O15
A19
A12
A13
/WE
I/O8
G
I/O8
/WE
A13
A12
A19
I/O16
A8
A9
A10
A11
GND
H
GND
A11
A10
A9
A8
A18
A0 - A19
: Address inputs
/OE
: Output enable
I/O1 - I/O16
: Data inputs / outputs
/LB, /UB
: Byte data select
/CS
: Chip Select
VCC
: Power supply
MODE
: Standby mode
GND
: Ground
/WE
: Write enable
Remark Refer to Package Drawing for the index mark.
Data Sheet M15085EJ4V0DS
3
µPD4616112
Block Diagram
Standby mode control
VCC
Refresh
control
GND
Memory cell array
16,777,216 bits
Refresh
counter
A0
A19
Row
decoder
Address
buffer
I/O1 - I/O8
I/O9 - I/O16
Input data
controller
Sense amplifier / Switching circuit
Column decoder
Address buffer
/CS
MODE
/LB
/UB
/WE
/OE
4
Data Sheet M15085EJ4V0DS
Output data
controller
µPD4616112
Truth Table
/CS
MODE
/OE
/WE
/LB
/UB
Mode
H
H
×
×
×
×
Not selected (Standby Mode 1)
I/O
Supply current
I/O1 - I/O8
I/O9 - I/O16
High impedance
High impedance
ISB1
H
L
×
×
×
×
Not selected (Standby Mode 2)
High impedance
High impedance
ISB2
L
H
H
H
×
×
Output disable
High impedance
High impedance
ICCA
L
H
×
L
L
L
Word read
DOUT
DOUT
L
H
Lower byte read
DOUT
High impedance
H
L
Upper byte read
High impedance
DOUT
H
H
Output disable
High impedance
High impedance
L
L
Word write
DIN
DIN
L
H
Lower byte write
DIN
High impedance
H
L
Upper byte write
High impedance
DIN
H
H
Write abort
High impedance
High impedance
Caution MODE pin must be fixed to High except Standby Mode 2.
Remark ×: VIH or VIL
Initialization
The µPD4616112 is initialized in the power-on sequence according to the following.
★
(1) To stabilize internal circuits, before turning on the power, a 200 µs or longer wait time must precede any signal
toggling.
(2) After the wait time, read operation must be performed at least 8 times. After that, it can be normal operation.
Initialization Timing Chart
VCC (MIN.)
VCC
Address (Input)
MODE (Input)
VIH (MIN.)
tRC
/CS (Input)
tCP
VIH (MIN.)
Power On Wait Time
Read Operation 8 times
200 µs
Normal
Operation
Cautions 1. Following power application, make MODE and /CS high level during the wait time interval.
2. Following power application, make MODE high level during the wait time and eight read
operations.
3. The read operation must satisfy the specs described on page 10 (Read Cycle (BC Version)).
4. The address is don’t care (VIH or VIL) during read operation.
5. Read operation must be executed with toggled the /CS pin.
6. To prevent bus contention, it is recommended to set /OE to high level. However, do not input
data to the I/O pins if /OE is low level during a read operation.
Data Sheet M15085EJ4V0DS
5
µPD4616112
Electrical Specifications
Absolute Maximum Ratings
Parameter
Supply voltage
Symbol
Condition
Rating
VCC
–0.5
–0.5
Note
Note
Unit
to +3.3
V
to VCC + 0.4 (3.3 V MAX).
V
Input / Output voltage
VT
Operating ambient temperature
TA
–20 to +70
°C
Storage temperature
Tstg
–55 to +125
°C
Note –1.0 V (MIN.) (Pulse width: 30 ns)
Caution Exposing the device to stress above those listed in Absolute Maximum Rating could cause
permanent damage. The device is not meant to be operated under conditions outside the limits
described in the operational section of this specification. Exposure to Absolute Maximum Rating
conditions for extended periods may affect device reliability.
Recommended Operating Conditions
Parameter
Symbol
µPD4616112-BCxx
Condition
Unit
MIN.
MAX.
Supply voltage
VCC
2.6
3.0
V
High level input voltage
VIH
VCC×0.8
VCC+0.3
V
VCC×0.2
V
+70
°C
Low level input voltage
VIL
Operating ambient temperature
TA
–0.3
Note
–20
Note –0.5 V (MIN.) (Pulse width: 30 ns)
Capacitance (TA = 25°°C, f = 1 MHz)
Parameter
Symbol
Test condition
MIN.
TYP.
MAX.
Unit
Input capacitance
CIN
VIN = 0 V
8
pF
Input / Output capacitance
CI/O
VI/O = 0 V
10
pF
Remarks 1. VIN: Input voltage
VI/O: Input / Output voltage
2. These parameters are not 100% tested.
6
Data Sheet M15085EJ4V0DS
µPD4616112
DC Characteristics (Recommended Operating Conditions Unless Otherwise Noted)
Parameter
Symbol
µPD4616112-BCxx
Test condition
MIN.
TYP.
Unit
MAX.
Input leakage current
ILI
VIN = 0 V to VCC
–1.0
+1.0
µA
I/O leakage current
ILO
VI/O = 0 V to VCC, /CS = VIH or
–1.0
+1.0
µA
35
mA
µA
/WE = VIL or /OE = VIH
Operating supply current
ICCA
/CS = VIL, Minimum cycle time,
II/O = 0 mA
ISB1
/CS ≥ VCC − 0.2 V, MODE ≥ VCC − 0.2 V
100
ISB2
/CS ≥ VCC − 0.2 V, MODE ≤ 0.2 V
10
High level output voltage
VOH
IOH = –0.5 mA
Low level output voltage
VOL
IOL = 1 mA
Standby supply current
VCC×0.8
V
VCC×0.2
V
Remarks 1. VIN: Input voltage
VI/O: Input / Output voltage
2. These DC characteristics are in common regardless of product classifications.
Data Sheet M15085EJ4V0DS
7
µPD4616112
Standby Mode State Machine
Power on
/CS = VIH,
MODE = VIH
Wait 200 µ s
Dummy read operation (8 times)
Initial State
/CS = VIL
/CS = VIH,
MODE = VIH
MODE = VIH
Active
/CS = VIH,
MODE = VIH
/CS = VIH,
MODE = VIL
/CS = VIL,
MODE = VIH
Standby
Mode1
/CS = VIH, MODE = VIL
Standby Mode Characteristics
8
Standby Mode
Memory Cell Data Hold
Standby Supply Current (µA)
Mode 1
Valid
100 (ISB1)
Mode 2
Invalid
10 (ISB2)
Data Sheet M15085EJ4V0DS
Standby
Mode2
µPD4616112
AC Characteristics (Recommended Operating Conditions Unless Otherwise Noted)
AC Test Conditions
[ µPD4616112-BC80, µPD4616112-BC90, µPD4616112-BC10 ]
Input Waveform (Rise and Fall Time ≤ 5 ns)
Vcc
Vcc x 0.8 V
Vcc/2 V
Test points
Vcc/2 V
Vcc x 0.2 V
GND
5ns
Output Waveform
Vcc/2 V
Test points
Vcc/2 V
Output Load
AC characteristics directed with the note should be measured with the output load shown in Figure 1.
Figure 1
CL: 50 pF
5 pF (tCLZ, tOLZ, tBLZ, tCHZ, tOHZ, tBHZ, tWHZ, tOW)
ZO = 50 Ω
I/O (Output)
50 Ω
CL
VCC/2 V
Data Sheet M15085EJ4V0DS
9
µPD4616112
Read Cycle (BC version)
Parameter
Symbol
µPD4616112-BC80 µPD4616112-BC90 µPD4616112-BC10
MIN.
MAX.
MIN.
MAX.
MIN.
MAX.
Unit
Notes
Read cycle time
tRC
80
10,000
90
10,000
110
10,000
ns
1
Identical address read cycle time
tRC1
80
10,000
90
10,000
110
10,000
ns
2
Address skew time
tSKEW
20
ns
3
10
10
15
/CS pulse width
tCP
10
10
ns
Address access time
tAA
80
90
100
ns
/CS access time
tACS
80
90
100
ns
/OE to output valid
tOE
35
40
50
ns
/LB, /UB to output valid
tBA
35
40
50
ns
Output hold from address change
tOH
10
10
10
ns
/CS to output in low impedance
tCLZ
10
10
10
ns
/OE to output in low impedance
tOLZ
5
5
5
ns
/LB, /UB to output in low impedance
tBLZ
5
5
5
ns
/CS to output in high impedance
tCHZ
25
25
25
ns
/OE to output in high impedance
tOHZ
25
25
25
ns
/LB, /UB to output in high impedance
tBHZ
25
25
25
ns
4
5
Notes 1. One read cycle (tRC) must satisfy the minimum value (tRC(MIN.)) and maximum value (tRC(MAX.) = 10 µs). tRC
indicates the time from the /CS low level input point or address determination point, whichever is later, to
the /CS high level input point or the next address change start point, whichever is earlier. As a result,
there are the following four conditions for tRC.
1) Time from address determination point to /CS high level input point
★
(address access)
2) Time from address determination point to next address change start point
(address access)
3) Time from /CS low level input point to next address change start point
(/CS access)
4) Time from /CS low level input point to /CS high level input point
(/CS access)
2. The identical address read cycle time (tRC1) is the cycle time of one read operation when performing
continuous read operations toggling /OE , /LB, and /UB with the address fixed and /CS low level. Perform
settings so that the sum (tRC) of the identical address read cycle times (tRC1) is 10 µs or less.
3. tSKEW indicates the following three types of time depending on the condition.
1) When switching /CS from high level to low level, tSKEW is the time from the /CS low level input point until
the next address is determined.
2) When switching /CS from low level to high level, tSKEW is the time from the address change start point to
the /CS high level input point.
3) When /CS is fixed to low level, tSKEW is the time from the address change start point until the next address
is determined.
Since specs are defined for tSKEW only when /CS is active, tSKEW is not subject to limitations when /CS is
switched from high level to low level following address determination, or when the address is changed after
/CS is switched from low level to high level.
4. Regarding tAA and tACS, only tAA is satisfied during address access (refer to 1) and 2) of Note 1), and only
tACS is satisfied during /CS access (refer to 3) of Note 1).
5. Regarding tBA and tOE, only tBA is satisfied if /OE becomes active later than /UB and /LB, and only tOE is
satisfied if /UB and /LB become active before /OE.
10
Data Sheet M15085EJ4V0DS
µPD4616112
Read Cycle Timing Chart 1
tSKEW
tSKEW
Address (Input)
tCP
tRC
tCP
/CS (Input)
tACS
tCHZ
tCLZ
/OE (Input)
tOE
tOHZ
tOLZ
/LB, /UB (Input)
tBA
tBHZ
tBLZ
tOH
High impedance
I/O (Output)
Data out
tSKEW
tSKEW
tRC
Address (Input)
tCP
tCP
tAA
/CS (Input)
tCHZ
tCLZ
/OE (Input)
tOE
tOHZ
tOLZ
/LB, /UB (Input)
tBA
tBHZ
tBLZ
I/O (Output)
High impedance
Data out
Caution If the address is changed using a value that is either lower than the minimum value or higher than
the maximum value for the read cycle time (tRC), none of the data can be guaranteed.
Remark In read cycle, /WE should be fixed to High.
Data Sheet M15085EJ4V0DS
11
12
Read Cycle Timing Chart 2
tSKEW
tRC
tSKEW
tRC
tSKEW
tSKEW
Address (Input)
tCP
tAA
tRC
tRC
tCP
tRC
tAA
tAA
Data Sheet M15085EJ4V0DS
/CS (Input)
tCLZ
tCHZ
tACS
tCHZ
tCLZ
/OE (Input)
tACS
tCHZ
tCLZ
tOE
tOLZ
tOHZ
/LB, /UB (Input)
tBA
tBHZ
tOH
tBLZ
tBA
tBHZ
tBLZ
I/O (Output)
tBA
tBHZ
tOH
tOH
tBLZ
High impedance
Data out
Data out
Data out
Data out
Data out
Caution If the address is changed using a value that is either lower than the minimum value or higher than the maximum value for the read cycle
Remark In read cycle, /WE should be fixed to High.
µPD4616112
time (tRC), none of the data can be guaranteed.
Read Cycle Timing Chart 3
tSKEW
tRC
tSKEW
tRC
tSKEW
tRC
tSKEW
tRC
tSKEW
tRC
Address (Input)
tAA
tAA
tAA
/CS (Input)
tCLZ
Data Sheet M15085EJ4V0DS
tBA
tBHZ
tBHZ
tOH
tBLZ
Hi-Z
tBA
tOH
tBA
tBHZ
tOH
tBLZ
High
impedance
tBLZ
Data out
Data out
/UB (Input)
tOHZ
tOLZ
tOLZ
tBA
/LB (Input)
I/O9 - 16 (Output)
tOHZ
tOHZ
tOLZ
I/O1 - 8 (Output)
tOE
tOE
tOE
/OE (Input)
Data out
tBHZ
tBLZ
tOH
Data out
time (tRC), none of the data can be guaranteed.
13
Remark In read cycle, /WE should be fixed to High.
µPD4616112
Caution If the address is changed using a value that is either lower than the minimum value or higher than the maximum value for the read cycle
µPD4616112
Read Cycle Timing Chart 4
tSKEW
tSKEW
tRC
Address (Input)
tRC1
Note
Note
tRC1
tAA
/CS (Input)
tOE
tOE
tOLZ
tOLZ
/OE (Input)
tOHZ
tBA
tBLZ
tBA
tBLZ
tOHZ
/LB, /UB (Input)
High impedance
I/O (Output)
tBHZ
tBHZ
Data out
Data out
High impedance
Caution If the address is changed using a value that is either lower than the minimum value or higher than
the maximum value for the read cycle time (tRC), none of the data can be guaranteed.
Note To perform a continuous read toggling /OE, /UB, and /LB with /CS low level at an identical address, make
settings so that the sum (tRC) of the identical address read cycle times (tRC1) is 10 µs or less.
Remark In read cycle, /WE should be fixed to High.
14
Data Sheet M15085EJ4V0DS
µPD4616112
Write Cycle (BC version)
Parameter
Symbol
µPD4616112-BC80 µPD4616112-BC90 µPD4616112-BC10
MIN.
MAX.
MIN.
MAX.
MIN.
MAX.
Unit
Notes
Write cycle time
tWC
80
10,000
90
10,000
110
10,000
ns
1
Identical address write cycle time
tWC1
80
10,000
90
10,000
110
10,000
ns
2
Address skew time
tSKEW
20
ns
3
/CS to end of write
tCW
40
50
60
ns
4
/LB, /UB to end of write
tBW
30
35
40
ns
Address valid to end of write
tAW
35
45
55
ns
Write pulse width
tWP
30
35
40
ns
Write recovery time
tWR
20
20
20
ns
/CS pulse width
tCP
10
10
10
ns
Address setup time
tAS
0
0
0
ns
Byte write hold time
tBWH
20
20
20
ns
Data valid to end of write
tDW
20
25
30
ns
Data hold time
tDH
0
0
0
ns
/OE to output in low impedance
tOLZ
5
5
5
ns
/WE to output in high impedance
tWHZ
25
25
25
ns
/OE to output in high impedance
tOHZ
25
25
25
ns
Output active from end of write
tOW
10
5
15
5
5
5
ns
Notes 1. One write cycle (tWC) must satisfy the minimum value (tWC(MIN.)) and the maximum value (tWC(MAX.) = 10 µs).
tWC indicates the time from the /CS low level input point or address determination point, whichever is after,
to the /CS high level input point or the next address change start point, whichever is earlier. As a result,
there are the following four conditions for tWC.
1) Time from address determination point to /CS high level input point
2) Time from address determination point to next address change start point
3) Time from /CS low level input point to next address change start point
4) Time from /CS low level input point to /CS high level input point
2. The identical address read cycle time (tWC1) is the cycle time of one write cycle when performing continuous
write operations with the address fixed and /CS low level, changing /LB and /UB at the same time, and
toggling /WE, as well as when performing a continuous write toggling /LB and /UB. Make settings so that
the sum (tWC) of the identical address write cycle times (tWC1) is 10 µs or less.
3. tSKEW indicates the following three types of time depending on the condition.
1) When switching /CS from high level to low level, tSKEW is the time from the /CS low level input point until
the next address is determined.
2) When switching /CS from low level to high level, tSKEW is the time from the address change start point to
the /CS high level input point.
3) When /CS is fixed to low level, tSKEW is the time from the address change start point until the next address
is determined.
Since specs are defined for tSKEW only when /CS is active, tSKEW is not subject to limitations when /CS is
switched from high level to low level following address determination, or when the address is changed after
/CS is switched from low level to high level.
Data Sheet M15085EJ4V0DS
15
µPD4616112
4. Definition of write start and write end
Write start pattern 1
/CS
/WE
/LB, /UB
Status
H to L
L
L
If /WE, /LB, /UB are low level, time when /CS
changes from high level to low level
Write start pattern 2
L
H to L
L
If /CS, /LB, /UB are low level, time when /WE
changes from high level to low level
Write start pattern 3
L
L
H to L
If /CS, /WE are low level, time when /LB or
/UB changes from high level to low level
Write end pattern 1
L
L to H
L
If /CS, /WE, /LB, /UB are low level, time when
/WE changes from low level to high level
Write end pattern 2
L
L
L to H
When /CS, /WE, /LB, /UB are low level, time
when /LB or /UB changes from low level to
high level
5. Definition of write end recovery time (tWR)
1) Time from write end to address change start point, or from write end to /CS high level input point
2) When /CS, /LB, /UB are low level and continuously written to the identical address, time from /WE high
level input point to /WE low level input point
3) When /CS, /WE are low level and continuously written to the identical address, time from /LB or /UB
high level input point, whichever is later, to /LB or /UB low level input point, whichever is earlier.
4) When /CS is low level and continuously written to the identical address, time from write end to point at
which /WE , /LB, or /UB starts to change from high level to low level, whichever is earliest.
16
Data Sheet M15085EJ4V0DS
µPD4616112
Write Cycle Timing Chart 1
tWC
tSKEW
tWC
tSKEW
Address (Input)
tAW
tAW
tCP
/CS (Input)
tWP
tAS
tWR
tWP
tWR
/WE (Input)
tAS
tBW
tBW
/LB, /UB (Input)
tDW
tDW
tDH
High impedance
I/O (Intput)
tDH
High impedance
Data in
Data in
tWC
tSKEW
tSKEW
tWC
tSKEW
Address (Input)
tCW
tCW
tCP
/CS (Input)
tWP
tWP
tWR
tWR
/WE (Input)
tBW
tBW
/LB, /UB (Input)
tDW
I/O (Intput)
tDW
tDH
High impedance
tDH
High impedance
Data in
Data in
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the write cycle time (tWC), none of the data can be guaranteed.
Remark
Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
Data Sheet M15085EJ4V0DS
17
µPD4616112
Write Cycle Timing Chart 2
tSKEW
tWC
tSKEW
tWC
tSKEW
tWC
tSKEW
tSKEW
Address (Input)
tAW
tAW
tCP
/CS (Input)
tCW
/WE (Input)
tWR
tWP
tAS
tAW
tWR
tWP
tOW
tWP
tWR
tWHZ
/OE (Input)
tDW
I/O (Intput / Output)
High impedance
tDH
tOLZ
tOHZ
tDW
Indefinite
data out
Data in
High
impedance
tDH
tDW
tDH
High impedance
Data in
High impedance
Data in
High
impedance
tSKEW
tSKEW
tWC
Address (Input)
tWC1 Note
Note
tWC1
/CS (Input)
tAS
tWP
tWR
tWP
tWR
/WE (Input)
tBW
/LB, /UB (Input)
tDW
I/O (Intput)
High impedance
tDH
Data in
tDW
High impedance
tDH
High impedance
Data in
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the write cycle time (tWC), none of the data can be guaranteed.
Note If /LB and /UB are changed at the same time with /CS low level and a continuous write operation toggling /WE
is performed, make settings so that the sum (tWC) of the identical address write cycle time (tWC1) is 10 µs or
less.
Remarks 1. Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
2. When /WE is at Low, the I/O pins are always high impedance. When /WE is at High, read operation is
executed. Therefore /OE should be at High to make the I/O pins high impedance.
18
Data Sheet M15085EJ4V0DS
µPD4616112
Write Cycle Timing Chart 3 (/CS Controlled)
Address (Input)
tWC
tWC
/CS (Input)
tAS
tWR
tCW
tAS
tCW
tWR
/WE (Input)
/LB, /UB (Input)
tDW
I/O (Intput)
High impedance
tDH
Data in
tDW
Hig impedance
tDH
High impedance
Data in
Address (Input)
tWC
tWC
/CS (Input)
tAS
tWR
tCW
tAS
tCW
tWR
/WE (Input)
/LB, /UB (Input)
tDW
I/O (Intput)
tDH
High impedance
tDW
tDH
High impedance
Data in
High impedance
Data in
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the write cycle time (tWC), none of the data can be guaranteed.
Remark Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
Data Sheet M15085EJ4V0DS
19
µPD4616112
Write Cycle Timing Chart 4 (/LB, /UB Controlled 1)
tWC
tSKEW
tWC
tSKEW
Address (Input)
tAW
tAW
/CS (Input)
tWP
/WE (Input)
tAS
tBW
tAS
tWR
tBW
tWR
/LB, /UB (Input)
tDW
I/O (Intput)
High impedance
tDW
tDH
High impedance
Data in
tSKEW
tWC
tDH
Data in
tWC
tSKEW
Address (Input)
tAW
tCW
/CS (Input)
tWP
/WE (Input)
tAS
tBW
tWR
tAS
tBW
tWR
/LB, /UB (Input)
tDW
I/O (Intput)
High impedance
tDW
tDH
Data in
High impedance
tDH
Data in
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the write cycle time (tWC), none of the data can be guaranteed.
Remark Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
20
Data Sheet M15085EJ4V0DS
µPD4616112
Write Cycle Timing Chart 5 (/LB, /UB Controlled 2)
tSKEW
tSKEW
tWC
Address (Input)
Note
Note
tWC1
tWC1
/CS (Input)
tWP
/WE (Input)
tAS
tBW
tWR
tWR
tBW
/LB, /UB (Input)
tDW
I/O (Intput)
High impedance
tDH
Data in
tDW
High impedance
tDH
Data in
High impedance
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the write cycle time (tWC), none of the data can be guaranteed.
Note If /LB and /UB are changed at the same time with /CS low level and a continuous write operation toggling /WE
is performed, make settings so that the sum (tWC) of the identical address write cycle time (tWC1) is 10 µs or
less.
Remark Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
Data Sheet M15085EJ4V0DS
21
µPD4616112
Write Cycle Timing Chart 6 (/LB, /UB Independent Controlled 1)
tWC
Address (Input)
tWC1
Note
tWC1
Note
/CS (Input)
tCW
tWP
/WE (Input)
/LB (Input)
tAS
tBW
tWR
tWR
tBW
/UB (Input)
tDW
High impedance
I/O1 - 8 (Intput)
tDH
High impedance
Data in
tDW
I/O9 - 16 (Intput)
tDH
High impedance
Data in
High
impedance
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the write cycle time (tWC), none of the data can be guaranteed.
Note If /LB and /UB are changed at the same time with /CS low level and a continuous write operation toggling /WE
is performed, make settings so that the sum (tWC) of the identical address write cycle time (tWC1) is 10 µs or
less.
Remark Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
22
Data Sheet M15085EJ4V0DS
µPD4616112
Write Cycle Timing Chart 7 (/LB, /UB Independent Controlled 2)
Address (Input)
tWC
/CS (Input)
tCW
tCW
tWP
tWP
/WE (Input)
tBW
tWR
/LB (Input)
tAS
tBWH
tWR
tBW
/UB (Input)
tAS
tDW
I/O1 - 8 (Intput)
High impedance
tDH
High impedance
Data in
tDW
I/O9 - 16 (Intput)
tDH
High impedance
High impedance
Data in
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the write cycle time (tWC), none of the data can be guaranteed.
Remark Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
Data Sheet M15085EJ4V0DS
23
µPD4616112
Read Write Cycle (BC version)
Parameter
Symbol
µPD4616112-BC80 µPD4616112-BC90 µPD4616112-BC10
MIN.
MAX.
MIN.
10,000
MAX.
MIN.
10,000
Unit
Notes
ns
1, 2
MAX.
Read write cycle time
tRWC
10,000
Byte write setup time
tBWS
20
20
20
ns
Byte read setup time
tBRS
20
20
20
ns
Notes 1. Make settings so that the sum (tRWC) of the identical address read cycle time (tRC1) and the identical address
write cycle time (tWC1) is 10 µs or less when a write is performed at the identical address using /UB following
a read using /LB with /CS low level, or when a write is performed using /LB following a read using /UB.
★
2. Make settings so that the sum (tRWC) of the identical address read cycle time (tRC1) and the identical address
write cycle time (tWC1) is 10 µs or less when a read is performed at the identical address using /UB following
a write using /LB with /CS low level, or when a read is performed using /LB following a write using /UB.
24
Data Sheet M15085EJ4V0DS
µPD4616112
Read Write Cycle Timing Chart 1 (/LB, /UB Independent Controlled 1)
tRWC
Address (Input)
tRC1
Note
Note
tWC1
tAA
/CS (Input)
tACS
tWP
/WE (Input)
tBWS
/LB (Input)
tWR
tBW
/UB (Input)
tCLZ
tBLZ
I/O1 - 8 (Output)
High impedance
tBHZ
High impedance
Data out
tDW
I/O9 - 16 (Intput)
tDH
High impedance
High impedance
Data in
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the identical address read cycle time (tRC1) and the identical address
write cycle time (tWC1), none of the data can be guaranteed.
Note Make settings so that the sum (tRWC) of the identical address read cycle time (tRC1) and the identical address
write cycle time (tWC1) is 10 µs or less when a write is performed at the identical address using /UB following a
read using /LB with /CS low level, or when a write is performed using /LB following a read using /UB.
Remark Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
Data Sheet M15085EJ4V0DS
25
µPD4616112
Read Write Cycle Timing Chart 2 (/LB, /UB Independent Controlled 2)
tRWC
Address (Input)
tWC1Note
tRC1 Note
tCW
/CS (Input)
tWR
tWP
/WE (Input)
tBW
/LB (Input)
tAS
tBRS
/UB (Input)
tDW
I/O1 - 8 (Input)
tDH
High impedance
High
impedance
Data in
tBA
tBHZ
tBLZ
I/O9 - 16 (Output)
High impedance
Data out
High
impedance
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the identical address read cycle time (tRC1) and the identical address
write cycle time (tWC1), none of the data can be guaranteed.
Note Make settings so that the sum (tRWC) of the identical address read cycle time (tRC1) and the identical address
write cycle time (tWC1) is 10 µs or less when a write is performed at the identical address using /UB following a
read using /LB with /CS low level, or when a write is performed using /LB following a read using /UB.
Remark Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
26
Data Sheet M15085EJ4V0DS
µPD4616112
Read Write Cycle Timing Chart 3 (/LB, /UB Independent Controlled 3)
tRWC
Address (Input)
tWC1Note
tRC1Note
tCW
/CS (Input)
tWR
tWP
/WE (Input)
tAS
tBW
/LB (Input)
/UB (Input)
tDW
I/O1 - 8 (Input)
High impedance
tDH
High
impedance
Data in
tBA
tBHZ
tBLZ
I/O9 - 16 (Output)
High impedance
Data out
High
impedance
Cautions 1. During address transition, at least one of pins /CS, /WE should be inactivated.
2. Do not input data to the I/O pins while they are in the output state.
3. If the address is changed using a value that is either lower than the minimum value or higher
than the maximum value for the identical address read cycle time (tRC1) and the identical address
write cycle time (tWC1), none of the data can be guaranteed.
Note Make settings so that the sum (tRWC) of the identical address read cycle time (tRC1) and the identical address
write cycle time (tWC1) is 10 µs or less when a write is performed at the identical address using /UB following a
read using /LB with /CS low level, or when a write is performed using /LB following a read using /UB.
Remark Write operation is done during the overlap time of a Low /CS, /WE, /LB and/or /UB.
Data Sheet M15085EJ4V0DS
27
µPD4616112
Standby Mode 2 entry and recovery Timing Chart
Address (Input)
MODE (Input)
tRC
/CS (Input)
tCM
Wait Time 200 µs
Standby
Mode 2
Parameter
/CS High to MODE Low
tCP
Symbol
MIN.
tCM
0
Read Operation 8 times
MAX.
Unit
Normal
Operation
Note
ns
Cautions 1. Make MODE and /CS high level during the wait time.
2. Make MODE high level during the wait time and eight read operations.
3. The read operation must satisfy the specs described on page 10 (Read Cycle (BC Version)).
4. The read operation address can be either VIH or VIL.
5. Perform reading by toggling /CS.
6. To prevent bus contention, it is recommended to set /OE to high level. However, do not input
data to the I/O pins if /OE is low level during a read operation.
28
Data Sheet M15085EJ4V0DS
µPD4616112
★
Package Drawing
48-PIN TAPE FBGA (6x8) (Unit : mm)
0.375
8.00
0.2 S A
48-φ 0.40
0.75
φ 0.08
S AB
M
0.75
φ 0.35 - 0.4
B
Index mark
6.00
0.375
1.5
A
Index mark (The reverse side)
0.5
0.2 S B
0.94
0.2 S
0.70
S
0.10 S
0.24
This package drawing is a preliminary version. It may be changed in the future.
Data Sheet M15085EJ4V0DS
29
µPD4616112
Recommended Soldering Conditions
Please consult with our sales offices for soldering conditions of the µPD4616112.
Type of Surface Mount Device
µPD4616112F9-BCxx-BC2: 48-pin TAPE FBGA (6 x 8)
30
Data Sheet M15085EJ4V0DS
µPD4616112
NOTES FOR CMOS DEVICES
1
PRECAUTION AGAINST ESD FOR SEMICONDUCTORS
Note:
Strong electric field, when exposed to a MOS device, can cause destruction of the gate oxide and
ultimately degrade the device operation. Steps must be taken to stop generation of static electricity
as much as possible, and quickly dissipate it once, when 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. Semiconductor 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. Semiconductor devices must not be touched with bare hands. Similar precautions need
to be taken for PW boards with semiconductor devices on it.
2
HANDLING OF UNUSED INPUT PINS FOR CMOS
Note:
No connection for CMOS device inputs can be 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 V DD or GND with a resistor, if it is considered to have a possibility of
being an output pin. All handling related to the unused pins must be judged device by device and
related specifications governing the devices.
3
STATUS BEFORE INITIALIZATION OF MOS DEVICES
Note:
Power-on does not necessarily define initial status of MOS device. Production process of MOS
does not define the initial operation status of the device. Immediately after the power source is
turned ON, the devices with reset function have not yet been initialized. Hence, power-on does
not guarantee out-pin levels, I/O settings or contents of registers. Device is not initialized until the
reset signal is received. Reset operation must be executed immediately after power-on for devices
having reset function.
Data Sheet M15085EJ4V0DS
31
µPD4616112
• The information in this document is current as of July, 2001. The information is subject to change
without notice. For actual design-in, refer to the latest publications of NEC's data sheets or data
books, etc., for the most up-to-date specifications of NEC semiconductor products. Not all products
and/or types are available in every country. Please check with an NEC sales representative for
availability and additional information.
• No part of this document may be copied or reproduced in any form or by any means without prior
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• Descriptions of circuits, software and other related information in this document are provided for illustrative
purposes in semiconductor product operation and application examples. The incorporation of these
circuits, software and information in the design of customer's equipment shall be done under the full
responsibility of customer. NEC assumes no responsibility for any losses incurred by customers or third
parties arising from the use of these circuits, software and information.
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agree and acknowledge that the possibility of defects thereof cannot be eliminated entirely. To minimize
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semiconductor products, customers must incorporate sufficient safety measures in their design, such as
redundancy, fire-containment, and anti-failure features.
• NEC semiconductor products are classified into the following three quality grades:
"Standard", "Special" and "Specific". The "Specific" quality grade applies only to semiconductor products
developed based on a customer-designated "quality assurance program" for a specific application. The
recommended applications of a semiconductor product depend on its quality grade, as indicated below.
Customers must check the quality grade of each semiconductor product before using it in a particular
application.
"Standard": Computers, office equipment, communications equipment, test and measurement equipment, audio
and visual equipment, home electronic appliances, machine tools, personal electronic equipment
and industrial robots
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systems, anti-crime systems, safety equipment and medical equipment (not specifically designed
for life support)
"Specific": Aircraft, aerospace equipment, submersible repeaters, nuclear reactor control systems, life
support systems and medical equipment for life support, etc.
The quality grade of NEC semiconductor products is "Standard" unless otherwise expressly specified in NEC's
data sheets or data books, etc. If customers wish to use NEC semiconductor products in applications not
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(Note)
(1) "NEC" as used in this statement means NEC Corporation and also includes its majority-owned subsidiaries.
(2) "NEC semiconductor products" means any semiconductor product developed or manufactured by or for
NEC (as defined above).
M8E 00. 4