Rohm BR93LC46FJ-W 64ã 16bits serial eeprom Datasheet

Memory ICs
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
64×16bits serial EEPROM
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
The BR93LC46-W series are CMOS serial input / output-type memory circuits (EEPROMs) that can be programmed
electrically. Each is configured of 64 words × 16 bits (1,024 bits), and each word can be accessed individually and data
read from it and written to it. Operation control is performed using five types of commands.
The commands, addresses, and data are input through the DI pin under the control of the CS and SK pins. In a write
operation, the internal status signal (READY or BUSY) can be output from the DO pin.
zApplications
VCRs, TVs, printers, car stereos, cordless telephones, short wave radios, programmable DIP switches, and
other battery-powered equipment requiring low voltage and low current
zFeatures
1) 64 words × 16 bits EEPROM
2) Operating voltage range
When reading : 2.0 to 5.5V
When writing : 2.7 to 5.5V
3) Low current consumption
Operating (at 5V) : 3mA (Max.)
Standby (at 5V) : 5µA (Max.)
4) Address can be incremented automatically during
read operations.
5) Auto erase and auto complete functions can be used
during write operations.
6) A write instruction inhibit function allows :
- write protection when power supply voltage is low.
- write disable state at power up.
- writing using command codes.
7) Compact packages
8) Display of READY / BUSY status
9) TTL-compatible input / output
10) Rewriting possible up to 100,000 times
11) Data can be stored for ten years without corruption.
zBlock diagram
Power supply
CS
voltage detector
Command decode
Control
Clock generation
SK
Address
Command
DI
Write
High voltage
disable
generator
6bits
Address
buffer
decoder
Data
R/W
6bits
register
1,024bits
16bits
register
DO
Dummy bits
amplifier
EEPROM array
16bits
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
Memory ICs
zPin descriptions
CS
1
SK
2
DI
3
DO
4
BR93LC46-W
BR93LC46RF-W
BR93LC46RFJ-W
8
VCC
N.C. 1
7
N.C.
VCC
2
6
N.C.
CS
3
5
GND
SK
4
Fig.1
BR93LC46F-W
BR93LC46FJ-W
BR93LC46FV-W
8
N.C.
7
GND
6
DO
5
DI
Fig.2
Pin No.
BR93LC46-W
BR93LC46RF-W
BR93LC46RFJ-W
BR93LC46F-W
BR93LC46FJ-W
BR93LC46FV-W
Pin
name
1
3
CS
2
4
SK
Serial clock input
3
5
DI
Start bit, operating code, address, and seria data input
4
6
DO
Serial data output, READY / BUSY internal status display output
5
7
GND
Ground
6
8
N.C.
Not connected
7
1
N.C.
Not connected
8
2
VCC
Power supply
Function
Chip select input
zAbsolute maximum ratings (Ta = 25°C)
Parameter
Applied voltage
Symbol
Limits
VCC
−0.3~+6.5
BR93LC46-W
Power
dissipation BR93LC46F-W / RF-W / FJ-W / RFJ-W
BR93LC46FV-W
Pd
Unit
500
∗1
350
∗2
300
V
mW
∗3
Storage temperature
Tstg
−65~+125
°C
Operating temperature
Topr
−40~+85
°C
−
−0.3~VCC+0.3
V
Terminal voltage
∗1 Reduced by 5.0mW for each increase in Ta of 1°C over 25°C.
∗2 Reduced by 3.5mW for each increase in Ta of 1°C over 25°C.
∗3 Reduced by 3.0mW for each increase in Ta of 1°C over 25°C.
zRecommended operating conditions (Ta = 25°C)
Parameter
Power supply
voltage
Input voltage
Symbol
Writing
Reading
VCC
VIN
Min.
Typ.
Max.
Unit
2.7
−
5.5
V
2.0
−
5.5
V
0
−
VCC
V
Memory ICs
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
zElectrical characteristics
For 5V operation (unless otherwise noted, Ta = −40 to + 85°C, VCC = 5.0V ± 10%)
Parameter
Symbol
Min.
Typ.
Max.
Unit
Conditions
Measurement circuit
Input low level voltage
VIL
−0.3
−
0.8
V
−
−
Input high level voltage
VIH
2.0
−
VCC+0.3
V
−
Output low level voltage 1
VOL1
−
−
0.4
V
Output high level voltage 1
VOH1
2.4
−
−
Output low level voltage 2
VOL2
−
−
0.2
Output high level voltage 2
VOH2
VCC−0.4
−
−
Input leakage current
ILI
−1.0
−
Output leakage current
ILO
−1.0
−
−
IOL=2.1mA
Fig.3
V
IOH=−0.4mA
Fig.4
V
IOL=10µA
Fig.3
V
IOH=−10µA
Fig.4
1.0
µA
VIN=0V~VCC
Fig.5
1.0
µA
VOUT=0V~VCC, CS=GND
Fig.6
Operating current
dissipation 1
ICC1
−
1.5
3.0
mA
Operating current
dissipation 2
ICC2
−
0.7
1.5
mA
Standby current
ISB
−
1.0
5.0
µA
VIN=VIH / VIL, DO=OPEN,
f=1MHz, WRITE
VIN=VIH / VIL, DO=OPEN,
f=1MHz, READ
CS=SK=DI=GND, DO=OPEN
Fig.7
Fig.7
Fig.8
For 3V operation (unless otherwise noted, Ta = −40 to + 85°C, VCC = 3.0V ± 10%)
Parameter
Symbol
Min.
Typ.
Max.
Unit
Conditions
Measurement circuit
VIL
−0.3
−
0.15×VCC
V
−
−
Input high level voltage
VIH
0.7×VCC
−
VCC+0.3
V
Output low level voltage
VOL
−
−
0.2
V
IOL=10µA
Fig.3
Output high level voltage
Input low level voltage
−
−
VOH
VCC−0.4
−
−
V
IOH=−10µA
Fig.4
Input leakage current
ILI
−1.0
−
1.0
µA
VIN=0V~VCC
Fig.5
Output leakage current
ILO
−1.0
−
1.0
µA
VOUT=0V~VCC, CS=GND
Fig.6
Operating current
dissipation 1
ICC1
−
0.5
2.0
mA
Operating current
dissipation 2
ICC2
−
0.2
1.0
mA
Standby current
ISB
−
0.4
3.0
µA
VIN=VIH / VIL, DO=OPEN
f=250kHz, WRITE
VIN=VIH / VIL, DO=OPEN
f=250kHz, READ
CS=SK=DI=GND, DO=OPEN
Fig.7
Fig.7
Fig.8
For 2V operation (unless otherwise noted, Ta = −40 to + 85°C, VCC = 2.0V)
Symbol
Min.
Typ.
Max.
Unit
Conditions
Measurement circuit
VIL
−0.3
−
0.15×VCC
V
−
−
Input high level voltage
VIH
0.7×VCC
−
VCC+0.3
V
Output low level voltage
VOL
−
−
0.2
V
IOL=10µA
Fig.3
Output high level voltage
Parameter
Input low level voltage
−
−
VOH
VCC−0.4
−
−
V
IOH=−10µA
Fig.4
Input leakage current
ILI
−1.0
−
1.0
µA
VIN=0V~VCC
Fig.5
Output leakage current
ILO
−1.0
−
1.0
µA
VOUT=0V~VCC, CS=GND
Fig.6
Operating current
dissipation 2
ICC2
−
0.2
1.0
mA
Standby current
ISB
−
0.4
3.0
µA
VIN=VIH / VIL, DO=OPEN
f=200kHz, READ
CS=SK=DI=GND, DO=OPEN
Fig.7
Fig.8
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
Memory ICs
zMeasurement circuits
VCC
VCC
VCC
VCC
IOL
IOH
DO
DO
GND
V
GND
VOL
V
Control output to "LOW"
Control output to "HIGH"
Fig.3 "LOW" output voltage circuit
Fig.4 "HIGH" output voltage circuit
VCC
VCC
VCC
VCC
ILO
ILI
CS,SK,DI
A
CS
VIN=0~VCC
DO
GND
VIN=VIH / VIL
Vcc
ICC
A
VCC
CS
VO=0~VCC
Fig.6 Output leak current circuit
VCC
A
SK
ISB
Vcc
CS
DO
OPEN
WRITE / READ INPUT
SK
DI
A
GND
Fig.5 Input leak current circuit
fSK=1MHz / 250kHz / 200kHz
VOH
DO
OPEN
GND
DI
GND
Fig.7 Supply current circuit
Fig.8 Standby current circuit
zCircuit operation
(1) Command mode
With these ICs, commands are not recognized or acted upon until the start bit is received. The start bit is taken as
the first “1” that is received after the CS pin rises.
Command
Start
bit
Operating
Address
code
Data
Read (READ) ∗1
1
10
A5~A0
Write enabled (WEN)
1
00
11XXXX
−
Write (WRITE) ∗2
1
01
A5~A0
D15~D0
Write all addresses (WRAL) ∗2
1
00
01XXXX
D15~D0
Write disabled (WDS)
1
00
00XXXX
−
Erase (ERASE) ∗3
1
11
A5~A0
−
Chip erase (ERAL) ∗3
1
00
10XXXX
−
−
X: Either VIH or VIL
∗1 After setting of the read command and input of the SK clock, data corresponding to the specified address is output,
with data corresponding to upper addresses then output in se-quence. (Auto increment function)
∗2 When the write or write all addresses command is executed, all data in the selected memory cell is erased
autematically, and the input data is writen to the cell.
∗3 These modes are optinal modes. Please contact Rohm for information on operation timing.
Memory ICs
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
(2) Operation timing characteristics
For 5V operation (unless otherwise noted, Ta = −40 to + 85°C, VCC = 5.0V ± 10%)
Symbol
Min.
Typ.
Max.
Unit
SK clock frequency
fSK
−
−
1
MHz
SK "HIGH" time
tSKH
450
−
−
ns
SK "LOW" time
tSKL
450
−
−
ns
CS "LOW" time
tCS
450
−
−
ns
CS setup time
tCSS
50
−
−
ns
DI setup time
tDIS
100
−
−
ns
CS hold time
tCSH
0
−
−
ns
DI hold time
tDIH
100
−
−
ns
Data "1" output delay time
tPD1
−
−
500
ns
Data "0" output delay time
tPD0
−
−
500
ns
Time from CS to output confirmation
tSV
−
−
500
ns
Time from CS to output High impedance
tDF
−
−
100
ns
tE / W
−
−
10
ms
Parameter
Write cycle time
For low voltage operation (unless otherwise noted, Ta = −40 to + 85°C, VCC = 3.0V ± 10%)
Symbol
Min.
Typ.
Max.
Unit
SK clock frequency
Parameter
fSK
−
−
250
kHz
SK "HIGH" time
tSKH
1
−
−
µs
SK "LOW" time
tSKL
1
−
−
µs
CS "LOW" time
tCS
1
−
−
µs
CS setup time
tCSS
200
−
−
ns
DI setup time
tDIS
400
−
−
ns
CS hold time
tCSH
0
−
−
ns
DI hold time
tDIH
400
−
−
ns
Data "1" output delay time
tPD1
−
−
2
µs
Data "0" output delay time
tPD0
−
−
2
µs
Time from CS to output confirmation
tSV
−
−
2
µs
Time from CS to output High impedance
tDF
−
−
400
ns
tE / W
−
−
25
ms
Write cycle time
When reading at low voltage (unless otherwise noted, Ta = −40 to + 85°C, VCC = 2.0V)
Symbol
Min.
Typ.
Max.
Unit
SK clock frequency
Parameter
fSK
−
−
200
kHz
SK "HIGH" time
tSKH
2
−
−
µs
SK "LOW" time
tSKL
2
−
−
µs
CS "LOW" time
tCS
2
−
−
µs
CS setup time
tCSS
400
−
−
ns
DI setup time
tDIS
800
−
−
ns
CS hold time
tCSH
0
−
−
ns
DI hold time
tDIH
800
−
−
ns
Data "1" output delay time
tPD1
−
−
4
µs
Data "0" output delay time
tPD0
−
−
4
µs
Time from CS to output High impedance
tDF
−
−
800
ns
Not designed for radiative rays.
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
Memory ICs
(3) Timing chart
CS
tCSS
tSKH
tDIS
tDIH
tCSH
tSKL
SK
DI
tPD0
tPD1
tDF
DO (READ)
tDF
STATUS VALID
DO (WRITE)
· Data is acquired from DI in synchronization with the SK rise.
· During a reading operation, data is output from DO in synchronization with the SK rise.
· During a writing operation, a Status Valid (READY or BUSY) is valid from the time CS is HIGH until time tCS after CS falls following the input of
a write command and before the output of the next command start bit. Also, DO must be in a HIGH-Z state when CS is LOW.
· After the completion of each mode, make sure that CS is set to LOW, to reset the internal circuit, before changing modes.
Fig.9 Synchronized data timing
(4) Reading (Fig.10)
When the read command is acknowledged, the data (16 bits) for the input address is output serially. The data is
synchronized with the SK rise during A0 acquisition and a “0” (dummy bit) is output. All further data is output in
synchronization with the SK pulse rises.
CS
(∗1)
SK
DI
1
2
1
1
4
0
A5
9
A4
A1
10
25
26
A0
(∗2)
0
DO
D15
D14
D1
D0
D15
D14
High Z
(∗1) If the first data input following the rise of the start bit CS is "1", the start bit is acknowledged. Also, if a "1" is input following several zeroes in succession, the
"1" is recognized as the start bit, and subsequent operation commences. This applies also to all commands described subsequently.
(∗2) Address auto increment function: These ICs are equipped with an address auto increment function which is effective only during reading operations. With
this function, if the SK clock is input following execution of one of the above reading commands, data is read from upper addresses in succession.
CS is held in HIGH state during automatic incrementing.
Fig.10 Read cycle timing (READ)
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
Memory ICs
(5) Write enable (Fig.11)
These ICs are set to the write disabled state by the internal reset circuit when the power is turned on. Therefore,
before performing a write command, the write enable command must be executed. When this command is
executed, it remains valid until a write disable command is issued or the power supply is cut off. However, read
commands can be used in either the write enable or write disable state.
CS
SK
DI
1
0
0
1
1
DO
High Z
Fig.11 Write enable cycle timing
(6) Write (Fig.12)
This command writes the input 16 bits data (D15 to D0) to the specified address (A5 to A0). Actual writing of the data
begins after CS falls (following the 25th clock pulse after the start bit input), and D0 is in the Acquire state.
STATUS is not detected if CS = LOW after the time tE / W. When STATUS is detected (CS = HIGH), no commands are
accepted while DO is LOW (BUSY). Therefore, no commands should be input during this period.
CS
SK
tCS
1
2
4
9
10
A0
D15
STATUS
25
DI
1
0
1
A5
A4
A1
D14
D1
D0
tSV
DO
BUSY
READY
High Z
tE / W
Fig.12 Write cycle timing (WRITE)
(STATUS)
After time tCS following the fall of CS, after input of the write command), if CS is set to HIGH, the write execute = BUSY
(LOW) and the command wait status READY (HIGH) are output.
If in the command wait status (STATUS = READY), the next command can be performed within the time tE / W. Thus, if
data is input via SK and DI with CS = HIGH in the tE / W period, erroneous operations may be performed. To avoid this,
make sure that DI = LOW when CS = HIGH. (Caution is especially important when common input ports are used.) This
applies to all of the write commands.
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
Memory ICs
(7) All address write (Fig.13)
With this command, the input 16 bits data is written simultaneously to all of the addresses (64 words). Rather than
writing one word at a time, in succession, data is written all at one time, enabling a write time of tE / W.
tSV
CS
STATUS
1
SK
2
5
10
1
D15
25
DI
1
0
0
0
D14
D1
D0
tCS
DO
BUSY
READY
High Z
tE / W
Fig.13 Write all address cycle timing. (WRAL)
(8) Write disable (Fig.14)
When the power supply is turned on, the IC enters the write disable status. Similarly, when the write disable command
is issued, the IC enters the same status. When in this status, all write commands are ignored, but read commands
may be executed.
In the write enable status, writing begins even if a write command is entered accidentally. To prevent errors of this type,
we recommend executing a write disable command after writing has been completed.
CS
SK
DI
1
0
0
0
0
DO
High Z
Fig.14 Write disable cycle timing (WDS)
zOperation notes
(1) Cancelling modes
〈READ〉
Start bit
1 bit
Operating code
2 bits
Address
Data
6 bits
16 bits
Cancel can be performed for the entire read mode space
Cancellation method: CS LOW
〈WRITE, WRAL〉
Start bit
1 bit
Operating code
2 bits
Address
Data
6 bits
16 bits
a
∗
a: Canceled by setting CS LOW or VCC OFF ( )
b: Cannot be canceled by any method. If VCC is set to OFF during this time, the data in the
designated address is not secured.
VCC OFF (VCC is turned off after CS is set to LOW)
∗
Fig.15
tE / W
b
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
Memory ICs
(2) Timing in the standby mode
As shown in Fig.16, during standby, if CS rises when SK is HIGH, the DI state may be read on the rising edge. If this
happens, and DI is HIGH, this is taken to be the start bit, causing a bit error (see point “a” in Fig.16).
Make sure all inputs are LOW during standby or when turning the power supply on or off (see Fig.17).
Point a: Start bit position during erroneous operation
Point b: Timing during normal operation
SK
SK
CS
CS
0
DI
1
0
DI
a
b
1
b
Fig. 17 Normal operation timing
Fig. 16 Erroneous operation timing
(3) Precautions when turning power on and off
When turning the power supply on and off, make sure CS is set to LOW (see Fig.18).
When CS is HIGH, the EEPROM enters the active state. To avoid this, make sure CS is set to LOW (disable mode)
when turning on the power supply. (When CS is LOW, all input is cancelled.)
When the power supply is turned off, the low power state can continue for a long time because of the capacity of the
power supply line. Erroneous operations and erroneous writing can occur at such times for the same reasons as
described above. To avoid this, make sure CS is set to LOW before turning off the power supply.
To prevent erroneous writing, these ICs are equipped with a POR (Power On Reset) circuit, but in order to achieve
operation at a low power supply, VCC is set to operate at approximately 1.3V. After the POR has been activated,
writing is disabled, but if CS is set to HIGH, writing may be enabled because of noise or other factors. However, the
POR circuit is effective only when the power supply is on, and will not operate when the power is off.
Also, to prevent erroneous writing at low voltages, these ICs are equipped with a built-in circuit (VCC-lockout circuit)
which resets the write command if VCC drops to approximately 2V or lower (typ.) (∗).
+ 5V
VCC
GND
+ 5V
CS
GND
Bad example
(Bad example)
(Good example)
Good example
Here, the CS pin is pulled up to VCC. In this case,
CS is HIGH (active state). Please be aware that the EEPROM may
perform erroneous operations or write erroneous data because of
noise or other factors. Please be aware that this can occur even if
the CS input is HIGH-Z.
In this case, CS is LOW when the power supply is turned
on or off.
Fig. 18
(4) Clock (SK) rise conditions
If the clock pin (SK) signal of the BR93LC46-W has a long rise time (tr) and if noise on the signal line exceeds a
certain level, erroneous operation can occur due to erroneous counts in the clock. To prevent this, a Schmitt trigger is
built into the SK input of the BR93LC46-W. The hysteresis amplitude of this circuit is set to approximately 0.2V, so if
the noise exceeds the SK input, the noise amplitude should be set to 0.2VP-P or lower. Furthermore, rises and falls in
the clock input should be accelerated as much as possible.
Memory ICs
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
(5) Power supply noise
The BR93LC46-W discharge high volumes of high voltage when a write is completed. The power supply may
fluctuate at such times. Therefore, make sure a capacitor of 1000pF or greater is connected between VCC (Pin 8) and
GND (Pin 5).
(6) Connecting DI and DO directly
The BR93LC46-W have an independent input pin (DI) and output pin (DO). These are treated as individual signals
on the timing chart but can be controlled through one control line. Control can be initiated on a single control line by
inserting a resistor R.
BR93LC46
µCOM
IO port
DI
R
DO
Fig. 19 Common connections for the DI and DO control line
1) Data collision between the µ-COM output and the DO output
Within the input and output timing of the BR93LC46-W the drive from the µ-COM output to the DI input and a signal
output from the DO output can be emitted at the same time. This happens only for the 1 clock cycle (a dummy bit
“0” is output to the DO pin) which acquires the A0 address data during a read cycle.
When the address data A0 = 1, the µ-COM output becomes a direct current source for the DO pin. The resistor R
is the only resistance which limits this current. Therefore, a resistor with a value which satisfies the µ-COM and the
BR93LC46-W current capacity is required. When using a single control line, when a dummy bit “0” is output to the
DO, the µ-COM I / O address data A0 is also output. Therefore, the dummy bit cannot be detected.
2) Feedback to the DI input from the DO output
Data is output from the DO pin and then feeds back into the DI input through the resistor R. This happens when:
DO data is output during a read operation
A READY / BUSY signal is output during WRITE or WRAL operation
Such feedback does not cause problems in the basic operation of the BR93LC46-W.
The µ-COM input level must be adequately maintained for the voltage drop at R which is caused by the total input
leakage current for the µ-COM and the BR93LC46-W. In the state in which SK is input, when the READY / BUSY
function is used, make sure that CS is dropped to LOW within four clock pulses of the output of the READY signal
HIGH and the standby mode is restored. For input after the fifth clock pulse, the READY HIGH will be taken as the
start bit and WDS or some other mode will be activated, depending on the DI state.
•
•
BR93LC46-W / BR93LC46F-W / BR93LC46RF-W /
BR93LC46FJ-W / BR93LC46RFJ-W / BR93LC46FV-W
Memory ICs
zExternal dimensions (Units : mm)
BR93LC46-W
BR93LC46F-W / RF-W
9.3 ± 0.3
5
5.0 ± 0.2
0.11
1.5 ± 0.1
0.51Min.
7.62
1
4
1.27 0.4 ± 0.1
2.54
0.5 ± 0.1
0.15
0°~15°
DIP8
SOP8
BR93LC46FJ-W / RFJ-W
BR93LC46FV-W
4.9 ± 0.2
3.0 ± 0.2
0.42 ± 0.1
5
1
4
0.22 ± 0.1
(0.52)
0.15 ± 0.1
0.1
1.15 ± 0.1
6.4 ± 0.3
0.2 ± 0.1
0.45Min.
1.27
8
4.4 ± 0.2
3.9 ± 0.2
1 2 3 4
0.175
6.0 ± 0.3
8 7 6 5
1.375 ±0.1
0.3Min.
0.3 ± 0.1
3.2± 0.2
3.4 ± 0.3
5
0.15 ± 0.1
4
8
4.4 ± 0.2
1
6.2 ± 0.3
6.5 ± 0.3
8
0.3Min.
0.65
0.1
0.1
SOP-J8
SSOP-B8
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