SANYO LE28CV1001M-12

Ordering number : EN*5409
CMOS LSI
LE28CV1001M, T-12/15
1MEG (131072 words × 8 bits) Flash Memory
Overview
Package Dimensions
The LE28CV1001M, T Series ICs are 1 MEG flash
memory products that feature a 131072-word × 8-bit
organization and 3.3 V single-voltage power supply
operation. CMOS peripheral circuits are adopted for high
speed, low power, and ease of use. A 128-byte page
rewrite function provides rapid data rewriting.
unit: mm
3205-SOP32
[LE28CV1001M]
Features
• Highly reliable 2-layer polysilicon CMOS flash
EEPROM process
• Read and write operations using a 5 V single-voltage
power supply
• Fast access time: 120 and 150 ns
• Low power dissipation
— Operating current (read): 12 mA (maximum)
— Standby current: 15 µA (maximum)
• Highly reliable read/write
—Erase/write cycles: 104/103 cycles
—Data retention time: 10 years
• Address and data latches
• Fast page rewrite operation
— 128 bytes per page
— Byte/page rewrite time: 5 ms (typical)
— Chip rewrite time: 5 s (typical)
• Automatic rewriting using internally generated Vpp
• Rewrite complete detection function
— Toggle bit
— Data polling
• Hardware and software data protection functions
• All inputs and outputs are TTL compatible.
• Pin assignment conforms to the JEDEC byte-wide
EEPROM standard.
• Package
SOP 32-pin (525 mil) plastic package:LE28CV1001M
TSOP 32-pin (8 × 20 mm) plastic package:LE28CV1001T
SANYO: SOP32
unit: mm
3224-TSOP32
[LE28CV1001T]
SANYO: TSOP32 (TYPE-I)
These FLASH MEMORY products incorporate technology licensed Silicon Storage Technology, Inc.
SANYO Electric Co.,Ltd. Semiconductor Bussiness Headquarters
TOKYO OFFICE Tokyo Bldg., 1-10, 1 Chome, Ueno, Taito-ku, TOKYO, 110 JAPAN
93096HA (OT) No. 5409-1/14
LE28CV1001M, T-12/15
Block Diagram
Pin Assignments
Pin Functions
Symbol
Pin
Function
Address input
Supply the memory address to these pins.
The address is latched internally during a write cycle.
Data input and output
These pins output data during a read cycle and input data during a write cycle.
Data is latched internally during a write cycle.
Outputs go to the high-impedance state when either OE or CE is high.
CE
Chip enable
The device is active when CE is low.
When CE is high, the device becomes unselected and goes to the standby state.
OE
Output enable
Makes the data output buffers active.
OE is a low-active input.
WE
Write enable
Makes the write operation active.
WE is an active-low input.
VDD
Power supply
Apply 3.3 V ±0.3 to this pin.
VSS
Ground
N.C.
No connection
A16 to A0
DQ7 to DQ0
These pins must be left open.
No. 5409-2/14
LE28CV1001M, T-12/15
Function Logic
Mode
CE
OE
WE
VIL
VIL
VIH
Write
VIL
VIH
Standby
VIH
X
X
X
Read
Write inhibit
A16 to A0
DOUT
VIL
AIN
DIN
X
X
High-Z
VIL
X
X
High-Z/DOUT
X
VIH
X
High-Z/DOUT
A16 to A10 = VIL, A8 to A1 = VIL,
Product identification
VIL
DQ7 to DQ0
AIN
VIL
VIH
A9 = 12 V, A0 = VIL
A16 to A10 = VIL, A8 to A1 = VIL,
A9 = 12 V, A0 = VIH
Manufacturer code (BF)
Device code (07)
Software Data Protection Command
Byte sequence
Set protection
Reset protection
Address
Data
Address
Data
Write 0
5555
AA
5555
AA
Write 1
2AAA
55
2AAA
55
Write 2
5555
A0
5555
80
Write 3
5555
AA
Write 4
2AAA
55
Write 5
5555
20
Note: Address format A14 to A0 (hex.)
Software Product ID Entry Command and Exit Command Codes
Byte sequence
Protect ID Entry
Protect ID Exit
Address
Data
Address
Data
Write 0
5555
AA
5555
AA
Write 1
2AAA
55
2AAA
55
Write 2
5555
80
5555
F0
Write 3
5555
AA
Write 4
2AAA
55
Write 5
5555
60
Notes on software Product ID Command Code:
1. Command Code Address format: A14 to A0 (hex.)
2. With A14 to A1 = VIL,
Manufacturer Code is read with A0 = VIL to be BFH
LE28CV1001M, T Device Code is read with A0 = VIH to be 07H
3. The device does not remain in Software Product ID Mode if powered down.
4. A16 and A15 at VIH or VIL.
No. 5409-3/14
LE28CV1001M, T-12/15
Device Operation
This Sanyo 1 MEG flash memory allows electrical rewrites using a 3.3 V single-voltage power supply. The
LE28CV1001M, T series products are pin and function compatible with the industry standards for this type of product.
Read
The LE28CV1001M, T series products read operations are controlled by CE and OE. The host must set both pins to the
low level to acquire the output data. CE is used for chip selection. When CE is at the high level, the chip will be in the
unselected state and only draw the standby current. OE is used for output control. The output pins go to the highimpedance state when either CE or OE is high. See the timing waveforms (Figure 1) for details.
Page Write Operation
The write operation starts when both CE and WE are at the low level, and furthermore OE is at the high level. The write
operation is executed in two stages. The first stage is a byte load cycle in which the host writes to the LE28CV1001M, T
series products internal page buffer. The second stage is an internal programming cycle in which the data in the page
buffer is written to the nonvolatile memory cell array. In the byte load cycle, the address is latched on the falling edge of
either CE or WE, whichever occurs later. The input data is latched on the rising edge of either CE or WE, whichever
occurs first. The internal programming cycle starts if either WE or CE remains high for 200 µs (t ). Once this
programming cycle starts, the operation continues until the programming operation is completely done. This operation
executes within 5 ms (typical). Figures 2 and 3 show the WE and CE control write cycle timing diagrams, and Figure 9
shows the flowchart for this operation.
In the page write operation, 128 bytes of data can be written to the LE28CV1001M, T series products internal page
buffer before the internal programming cycle. All the data in the page buffer is written to the memory cell array during
the 5 ms (typical) internal programming cycle. Therefore the LE28CV1001M, T series products page write function can
rewrite all memory cells in 5 seconds (typical). The host can perform any other activities desired, such as moving data at
other locations within the system and preparing the data required for the next page write, during the period prior to the
completion of the internal programming cycle. In a given page write operation, all the data bytes loaded into the page
buffer must be for the same page address specified by address lines A7 through A16. All data that was not explicitly
loaded into the page buffer is set to FFH.
Figure 2 shows the page write cycle timing diagram. If the host loads the second data byte into the page buffer within the
100 µs byte load cycle time (t ) after the first byte load cycle the LE28CV1001M, T series products stop in the page
load cycle thus allowing data to be loaded continuously. The page load cycle terminates if additional data is not loaded
into the internal page buffer within 200 µs (t ) after the previous byte load cycle, as in the case where WE does not
switch from high to low after the last WE rising edge. The data in the page buffer can be rewritten in the next byte load
cycle.
The page load period can continue indefinitely as long as the host continues to load data into the device within the 100 µs
byte load cycle. The page that is loaded is determined by the page address of the last byte loaded.
BLCO
BLC
BLCO
Detecting the Write Operation State
The LE28CV1001M, T series products provide two functions for detecting the completion of the write cycle. These
functions are used to optimize the system write cycle time. These functions are based on detecting the states of the Data
polling bit (DQ7) and the toggle bit (DQ6).
Data Polling (DQ7)
The LE28CV1001M, T series products output to DQ7 the inverse of the last data loaded during the page and byte load
cycles when the internal programming cycle is in progress. The last data loaded will be read from DQ7 when the internal
programming cycle completes. Figure 4 shows the Data polling cycle timing diagram and Figure 10 shows the flowchart
for this operation.
No. 5409-4/14
LE28CV1001M, T-12/15
Toggle Bit (DQ6)
Data values of 0 and 1 are output alternately for DQ6, that is DQ6 is toggled between 0 and 1, during the internal
programming cycle. When the internal programming cycle completes this toggling is stopped and the device becomes
ready to execute the next operation. Figure 5 shows the toggle bit timing diagram and Figure 10 shows the flowchart for
this operation.
Data Protection
Hardware Data Protection
Noise and glitch protection: The LE28CV1001 does not execute write operations for WE or OE pulses that are 15 ns or
shorter.
Power (VDD) on and cutoff detection: The programming operation is disabled when VDD is 2.5 V or lower.
Write inhibit mode: Writing is disabled when OE is low and either CE is high or WE is high. Use this function to prevent
writes from occurring when the power is being turned on or off.
Software Data Protection
The LE28CV1001 implements the optional software data protection function recognized by JEDEC. This function
requires that a 3-byte load operation to be performed before a write operation data load. The 3-byte load sequence starts
a page load cycle without activating any write operation. Thus this is an optimal protection scheme for unintended write
cycles triggered by noise associated with powering the chip on or off. Note that the LE28CV1001 is shipped with the
software data protection function disabled.
The software data protection circuit is activated by executing a 3-byte byte load cycle in advance of the data sequence in
the page load cycle. (See Figure 6.) This causes the device to automatically enter data protection mode. After this, write
operations require a 3-byte byte load cycle to be executed in advance. A 6-byte write sequence is required to switch the
device out of this protection mode. Figure 7 shows the timing diagram. If a write operation is attempted in software
protection mode, all device functions are disabled for 200 µs. Figure 11 shows the flowchart for this operation.
Product Identification
The device identification code is used for recognizing the device and its manufacturer. This mode can be used by
hardware and software. The hardware operating mode is used to recognize algorithms that match the device when an
external programming unit is used. Also, user systems can recognize the product number using software product
identification mode. Figure 12 shows the flowchart for this operation. The manufacturer and device codes are the same
in both modes.
No. 5409-5/14
LE28CV1001M, T-12/15
Specifications
Absolute Maximum Ratings at Ta = 25°C
Parameter
Symbol
Ratings
Unit
Note
Supply voltage
VDD
–0.5 to +6.0
V
1
Input pin voltage
VIN
–0.5 to VDD + 0.5
V
1, 2
DQ pin voltage
VOUT
–0.5 to VDD + 0.5
V
1, 2
A9 pin voltage
VA9
–0.5 to +14.0
V
1, 3
mW
1, 4
Allowable power dissipation
Pd max
600
Operating temperature
Topr
0 to +70
°C
1
Storage temperature
Tstg
–65 to +150
°C
1
Notes:1. The device may be destroyed by the application of stresses in excess of the absolute maximum ratings.
2. –1.0 V to VDD + 1.0 V for pulses less than 20 ns
3. –1.0 V to +14 V for pulses less than 20 ns
DC Recommended Operating Ranges at Ta = 0 to +70°C
Symbol
min
typ
max
Unit
Supply voltage
Parameter
VDD
3.0
3.3
3.6
V
Input low-level voltage
VIL
Input high-level voltage
VIH
0.6
V
2.0
V
DC Electrical Characteristics at Ta = 0 to +70°C, VDD = 3.3 V ± 0.3 V
Parameter
Symbol
Conditions
min
typ
max
Unit
12
mA
15
mA
1
mA
Current drain during read
ICCR
CE = OE = VIL, WE = VIH, all DQ pins open,
address inputs = VIH or VIL, operating frequency =
1/tRC (minimum), VDD = VDD max
Current drain during write
ICCW
CE = WE = VIL, OE = VIH, VDD = VDD max
TTL standby current
ISB1
CE = OE = WE = VIH, VDD = VDD max
CMOS standby current
ISB2
CE = OE = WE = VDD – 0.3 V,
VDD = VDD max
20
µA
Input leakage current
ILI
VIN = VSS to VDD, VDD = VDD max
10
µA
Output leakage current
ILO
VIN = VSS to VDD, VDD = VDD max
10
µA
Output low-level voltage
VOL
IOL = 2.1 mA, VDD = VDD min
0.4
V
Output high-level voltage
VOH
IOH = –400 µA, VDD = VDD min
2.4
V
Input/Output Pin Capacitances at Ta = 25°C, VDD = 3.3 V ± 0.3 V, f = 1 MHz
Parameter
Symbol
Conditions
max
Unit
Input/output capacitance
CDQ
VDQ = 0 V
12
pF
Input capacitance
CIN
VIN = 0 V
6
pF
max
Unit
Power on Timing
Parameter
Symbol
Conditions
Time from power on until first read operation
tPU-READ
100
µs
Time from power on until first write operation
tPU-WRITE
5
ms
No. 5409-6/14
LE28CV1001M, T-12/15
AC Electrical Characteristics at Ta = 0 to +70°C, VDD = 3.3 V ± 0.3 V
AC Testing Conditions (See Figure 8)
Input rise and fall time: ..................10 ns (max.)
Output load: ....................................1 TTL gate + 30 pF
Read Cycle
LE28CV1001M, T
Parameter
Symbol
-12
min
-15
max
min
Unit
max
Read cycle time
tRC
CE access time
tCE
120
150
Address access time
tAA
120
150
ns
OE access time
tOE
80
90
ns
120
150
Output low-impedance time from CE
tCLZ
0
0
Output low-impedance time from OE
tOLZ
0
0
Output high-impedance time from CE
tCHZ
Output high-impedance time from OE
tOHZ
Output valid time from address input
tOH
ns
ns
ns
50
50
0
ns
50
ns
50
ns
0
ns
Page Write Cycle
Parameter
Symbol
min
typ*
max
Unit
5
10
ms
Write cycle time (erase and program)
tWC
Address setup time
tAS
0
Address hold time
tAH
100
ns
CE setup time
tCS
0
ns
CE hold time
tCH
0
ns
OE setup time
tOES
0
ns
OE hold time
tOEH
0
ns
CE pulse width
tCP
120
ns
WE pulse width
tWP
120
ns
Data setup time
tDS
100
ns
Data hold time
tDH
0
ns
Byte load cycle time
tBLC
0.10
Byte load time out time
tBLCO
200
ns
100
µs
µs
Note: * typ is reference value at VDD = 3.3 V and Ta = 25°C
Figure 1 Read Cycle
No. 5409-7/14
LE28CV1001M, T-12/15
Figure 2 WE Control Page Write Cycle
Figure 3 CE Control Page Write Cycle
No. 5409-8/14
LE28CV1001M, T-12/15
Figure 4 Data Polling
Figure 5 Toggle Bit
Figure 6 Enable Software Data Protection
No. 5409-9/14
LE28CV1001M, T-12/15
Figure 7 Disable Software Data Protection
Figure 8 AC I/O Reference Waveform
No. 5409-10/14
LE28CV1001M, T-12/15
Figure 9 Write Algorithm
No. 5409-11/14
LE28CV1001M, T-12/15
Figure 10 Write Operating State Detection
No. 5409-12/14
LE28CV1001M, T-12/15
Figure 11 Software Data Protection Flowcharts
No. 5409-13/14
LE28CV1001M, T-12/15
Figure 12 Product ID Flowcharts
■ No products described or contained herein are intended for use in surgical implants, life-support systems, aerospace
equipment, nuclear power control systems, vehicles, disaster/crime-prevention equipment and the like, the failure of
which may directly or indirectly cause injury, death or property loss.
■ Anyone purchasing any products described or contained herein for an above-mentioned use shall:
➀ Accept full responsibility and indemnify and defend SANYO ELECTRIC CO., LTD., its affiliates, subsidiaries and
distributors and all their officers and employees, jointly and severally, against any and all claims and litigation and all
damages, cost and expenses associated with such use:
➁ Not impose any responsibility for any fault or negligence which may be cited in any such claim or litigation on
SANYO ELECTRIC CO., LTD., its affiliates, subsidiaries and distributors or any of their officers and employees
jointly or severally.
■ Information (including circuit diagrams and circuit parameters) herein is for example only; it is not guaranteed for
volume production. SANYO believes information herein is accurate and reliable, but no guarantees are made or implied
regarding its use or any infringements of intellectual property rights or other rights of third parties.
This catalog provides information as of September, 1996. Specifications and information herein are subject to
change without notice.
No. 5409-14/14