ATMEL AT49BV640D-70CU

Features
• Single Voltage Operation Read/Write: 2.65V - 3.6V
• Access Time – 70 ns
• Sector Erase Architecture
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– One Hundred Twenty-seven 32K Word (64K Bytes) Main Sectors with
Individual Write Lockout
– Eight 4K Word (8K Bytes) Sectors with Individual Write Lockout
Fast Word Program Time – 10 µs
Typical Sector Erase Time: 32K Word Sectors – 700 ms; 4K Word Sectors – 100 ms
Suspend/Resume Feature for Erase and Program
– Supports Reading and Programming Data from Any Sector by Suspending
Erase of a Different Sector
– Supports Reading Any Word by Suspending Programming of Any Other Word
Low-power Operation
– 10 mA Active
– 15 µA Standby
VPP Pin for Write Protection and Accelerated Program Operation
WP Pin for Sector Protection
RESET Input for Device Initialization
Flexible Sector Protection
Top or Bottom Boot Block Configuration Available
128-bit Protection Register
Minimum 100,000 Erase Cycles
Common Flash Interface (CFI)
Green (Pb/Halide-free/RoHS Compliant) Packaging
64-megabit
(4M x 16)
3-volt Only
Flash Memory
AT49BV640D
AT49BV640DT
1. Description
The AT49BV640D(T) is a 2.7-volt 64-megabit Flash memory organized as 4,194,304
words of 16 bits each. The memory is divided into 135 sectors for erase operations.
The device is offered in a 48-ball CBGA package. The device has CE and OE control
signals to avoid any bus contention. This device can be read or reprogrammed using
a single power supply, making it ideally suited for in-system programming.
The device powers on in the read mode. Command sequences are used to place
the device in other operation modes such as program and erase. The device has
the capability to protect the data in any sector (see “Flexible Sector Protection” on
page 6).
To increase the flexibility of the device, it contains an Erase Suspend and Program
Suspend feature. This feature will put the erase or program on hold for any amount of
time and let the user read data from or program data to any of the remaining sectors
within the memory.
The VPP pin provides data protection. When the VPP input is below 0.4V, the program
and erase functions are inhibited. When VPP is at 1.65V or above, normal program
and erase operations can be performed. With VPP at 10.0V, the program (Dual-word
Program command) operation is accelerated.
3608C–FLASH–11/06
2. Pin Configurations
Pin Name
Pin Function
A0 - A21
Addresses
CE
Chip Enable
OE
Output Enable
WE
Write Enable
RESET
Reset
VPP
Write Protection and Power Supply for Accelerated Program Operations
I/O0 - I/O15
Data Inputs/Outputs
NC
No Connect
VCCQ
Output Power Supply
WP
Write Protect
2.1
48-ball CBGA – Top View
1
2
3
4
5
6
7
8
A13
A11
A8
VPP
WP
A19
A7
A4
A14
A10
WE RESET A18
A17
A5
A2
A15
A12
A9
A6
A3
A1
A16 I/O14 I/O5 I/O11 I/O2
I/O8
CE
A0
VCCQ I/O15 I/O6 I/O12 I/O3
I/O9
I/O0
GND
A
B
C
A21
A20
D
E
F
GND
2
I/O7 I/O13 I/O4
VCC I/O10 I/O1
OE
AT49BV640D(T)
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AT49BV640D(T)
3. Block Diagram
I/O0 - I/O15
INPUT
BUFFER
INPUT
BUFFER
IDENTIFIER
REGISTER
STATUS
REGISTER
DATA
REGISTER
A0 - A21
OUTPUT
MULTIPLEXER
OUTPUT
BUFFER
CE
WE
OE
RESET
WP
COMMAND
REGISTER
ADDRESS
LATCH
DATA
COMPARATOR
Y-DECODER
Y-GATING
WRITE STATE
MACHINE
PROGRAM/ERASE
VOLTAGE SWITCH
VPP
VCC
GND
X-DECODER
MAIN
MEMORY
4. Device Operation
4.1
Command Sequences
When the device is first powered on, it will be in the read mode. Command sequences are
used to place the device in other operating modes such as program and erase. The command
sequences are written by applying a low pulse on the WE input with CE low and OE high or by
applying a low-going pulse on the CE input with WE low and OE high. The address is latched
on the first rising edge of the WE or CE. Valid data is latched on the rising edge of the WE or
the CE pulse, whichever occurs first. The addresses used in the command sequences are not
affected by entering the command sequences.
4.2
Read
The AT49BV640D(T) is accessed like an EPROM. When CE and OE are low and WE is high,
the data stored at the memory location determined by the address pins are asserted on the
outputs. The outputs are put in the high impedance state whenever CE or OE is high. This
dual-line control gives designers flexibility in preventing bus contention.
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4.3
Reset
A RESET input pin is provided to ease some system applications. When RESET is at a logic
high level, the device is in its standard operating mode. A low level on the RESET pin halts the
present device operation and puts the outputs of the device in a high-impedance state. When
a high level is reasserted on the RESET pin, the device returns to read mode.
4.4
Erase
Before a word can be reprogrammed it must be erased. The erased state of the memory bits is
a logical “1”. The individual sectors can be erased by using the Sector Erase command.
4.4.1
Sector Erase
The device is organized into 135 sectors (SA0 - SA134) that can be individually erased. The
Sector Erase command is a two-bus cycle operation. The sector address and the D0H Data
Input command are latched on the rising edge of WE. The sector erase starts after the rising
edge of WE of the second cycle provided the given sector has not been protected. The erase
operation is internally controlled; it will automatically time to completion. The maximum time to
erase a sector is tSEC. An attempt to erase a sector that has been protected will result in the
operation terminating immediately.
4.5
Word Programming
Once a memory sector is erased, it is programmed (to a logical “0”) on a word-by-word basis.
Programming is accomplished via the Internal Device command register and is a two-bus
cycle operation. The device will automatically generate the required internal program pulses.
Any commands except Read Status Register, Program Suspend and Program Resume written to the chip during the embedded programming cycle will be ignored. If a hardware reset
happens during programming, the data at the location being programmed will be corrupted.
Please note that a data “0” cannot be programmed back to a “1”; only erase operations can
convert “0”s to “1”s. Programming is completed after the specified tBP cycle time. If the program status bit is a “1”, the device was not able to verify that the program operation was
performed successfully. The status register indicates the programming status. While the program sequence executes, status bit I/O7 is “0”.
4.6
VPP Pin
The circuitry of the AT49BV640D(T) is designed so that the device cannot be programmed or
erased if the VPP voltage is less that 0.4V. When VPP is at 1.65V or above, normal program
and erase operations can be performed. The VPP pin cannot be left floating.
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AT49BV640D(T)
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AT49BV640D(T)
4.7
Read Status Register
The status register indicates the status of device operations and the success/failure of that
operation. The Read Status Register command causes subsequent reads to output data from
the status register until another command is issued. To return to reading from the memory,
issue a Read command.
The status register bits are output on I/O7 - I/O0. The upper byte, I/O15 - I/O8, outputs 00H
when a Read Status Register command is issued.
The contents of the status register [SR7:SR0] are latched on the falling edge of OE or CE
(whichever occurs last), which prevents possible bus errors that might occur if status register
contents change while being read. CE or OE must be toggled with each subsequent status
read, or the status register will not indicate completion of a Program or Erase operation.
When the Write State Machine (WSM) is active, SR7 will indicate the status of the WSM; the
remaining bits in the status register indicate whether the WSM was successful in performing
the preferred operation (see Table 4-1).
Table 4-1.
Status Register Bit Definition
WSMS
ESS
ES
PRS
VPPS
PSS
SLS
R
7
6
5
4
3
2
1
0
Notes
SR7 WRITE STATE MACHINE STATUS (WSMS)
1 = Ready
0 = Busy
Check Write State Machine bit first to determine Word Program
or Sector Erase completion, before checking program or erase
status bits.
SR6 = ERASE SUSPEND STATUS (ESS)
1 = Erase Suspended
0 = Erase In Progress/Completed
When Erase Suspend is issued, WSM halts execution and sets
both WSMS and ESS bits to “1” – ESS bit remains set to “1” until
an Erase Resume command is issued.
SR5 = ERASE STATUS (ES)
1 = Error in Sector Erase
0 = Successful Sector Erase
When this bit is set to “1”, WSM has applied the max number of
erase pulses to the sector and is still unable to verify successful
sector erasure.
SR4 = PROGRAM STATUS (PRS)
1 = Error in Programming
0 = Successful Programming
When this bit is set to “1”, WSM has attempted but failed to
program a word
SR3 = VPP STATUS (VPPS)
1 = VPP Low Detect, Operation Abort
0 = VPP OK
The VPP status bit does not provide continuous indication of VPP
level. The WSM interrogates VPP level only after the Program or
Erase command sequences have been entered and informs the
system if VPP has not been switched on. The VPP is also checked
before the operation is verified by the WSM.
SR2 = PROGRAM SUSPEND STATUS (PSS)
1 = Program Suspended
0 = Program in Progress/Completed
When Program Suspend is issued, WSM halts execution and
sets both WSMS and PSS bits to “1”. PSS bit remains set to “1”
until a Program Resume command is issued.
SR1 = SECTOR LOCK STATUS (SLS)
1 = Prog/Erase attempted on a locked sector; Operation aborted.
0 = No operation to locked sectors
If a Program or Erase operation is attempted to one of the locked
sectors, this bit is set by the WSM. The operation specified is
aborted and the device is returned to read status mode.
SR0 = Reserved for Future Enhancements (R)
This bit is reserved for future use and should be masked out
when polling the status register.
Note:
1. A Command Sequence Error is indicated when SR1, SR3, SR4 and SR5 are set.
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4.8
Clear Status Register
The WSM can set status register bits 1 through 7 and can clear bits 2, 6 and 7; but, the WSM
cannot clear status register bits 1, 3, 4 or 5. Because bits 1, 3, 4 and 5 indicate various error
conditions, these bits can be cleared only through the Clear Status Register command. By
allowing the system software to control the resetting of these bits, several operations may be
performed (such as cumulatively programming several addresses or erasing multiple sectors
in sequence) before reading the status register to determine if an error occurred during those
operations. The status register should be cleared before beginning another operation. The
Read command must be issued before data can be read from the memory array. The status
register can also be cleared by resetting the device.
4.9
Flexible Sector Protection
The AT49BV640D(T) offers two sector protection modes, the Softlock and the Hardlock. The
Softlock mode is optimized as sector protection for sectors whose content changes frequently.
The Hardlock protection mode is recommended for sectors whose content changes infrequently. Once either of these two modes is enabled, the contents of the selected sector is
read-only and cannot be erased or programmed. Each sector can be independently programmed for either the Softlock or Hardlock sector protection mode. At power-up and reset, all
sectors have their Softlock protection mode enabled.
4.9.1
Softlock and Unlock
The Softlock protection mode can be disabled by issuing a two-bus cycle Unlock command to
the selected sector. Once a sector is unlocked, its contents can be erased or programmed. To
enable the Softlock protection mode, a two-bus cycle Softlock command must be issued to the
selected sector.
4.9.2
Hardlock and Write Protect (WP)
The Hardlock sector protection mode operates in conjunction with the Write Protection (WP)
pin. The Hardlock sector protection mode can be enabled by issuing a two-bus cycle Hardlock
software command to the selected sector. The state of the Write Protect pin affects whether
the Hardlock protection mode can be overridden.
• When the WP pin is low and the Hardlock protection mode is enabled, the sector cannot be
unlocked and the contents of the sector is read-only.
• When the WP pin is high, the Hardlock protection mode is overridden and the sector can be
unlocked via the Unlock command.
To disable the Hardlock sector protection mode, the chip must be either reset or power cycled.
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AT49BV640D(T)
Table 4-2.
Hardlock and Softlock Protection Configurations in Conjunction with WP
WP
Hardlock
Softlock
Erase/
Prog
Allowed?
VCC/5V
0
0
0
Yes
No sector is locked
VCC/5V
0
0
1
No
Sector is Softlocked. The Unlock
command can unlock the sector.
VCC/5V
0
1
1
No
Hardlock protection mode is
enabled. The sector cannot be
unlocked.
VCC/5V
1
0
0
Yes
No sector is locked.
VCC/5V
1
0
1
No
Sector is Softlocked. The Unlock
command can unlock the sector.
VCC/5V
1
1
0
Yes
Hardlock protection mode is
overridden and the sector is not
locked.
VCC/5V
1
1
1
No
Hardlock protection mode is
overridden and the sector can be
unlocked via the Unlock command.
VIL
x
x
x
No
Erase and Program Operations
cannot be performed.
VPP
Figure 4-1.
Comments
Sector Locking State Diagram
UNLOCKED
LOCKED
60h/
D0h
60h/01h
[000]
[001]
60
h/2
Fh
Power-Up/Reset
Default
60h/
2Fh
WP = VIL = 0
Hardlocked
[011]
60h/D0h
[110]
60h/
01h
60h/
2Fh
WP = VIH = 1
60h/
D0h
[100]
Hardlocked is disabled by
WP = VIH
[111]
60h/
2Fh
Power-Up/Reset
Default
60h/
01h
[101]
60h/D0h = Unlock Command
60h/01h = Softlock Command
60h/2Fh = Hardlock Command
Note:
1. The notation [X, Y, Z] denotes the locking state of a sector. The current locking state of a
sector is defined by the state of WP and the two bits of the sector-lock status D[1:0].
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3608C–FLASH–11/06
4.9.3
Sector Protection Detection
A software method is available to determine if the sector protection Softlock or Hardlock features are enabled. When the device is in the software product identification mode a read from
the I/O0 and I/O1 at address location 00002H within a sector will show if the sector is
unlocked, softlocked, or hardlocked.
Table 4-3.
4.10
Sector Protection Status
I/O1
I/O0
Sector Protection Status
0
0
Sector Not Locked
0
1
Softlock Enabled
1
0
Hardlock Enabled
1
1
Both Hardlock and Softlock Enabled
Erase Suspend/Erase Resume
The Erase Suspend command allows the system to interrupt a sector erase operation and
then program or read data from a different sector within the memory. After the Erase Suspend
command is given, the device requires a maximum time of 15 µs to suspend the erase operation. After the erase operation has been suspended, the system can then read data or
program data to any other sector within the device. An address is not required during the
Erase Suspend command. During a sector erase suspend, another sector cannot be erased.
To resume the sector erase operation, the system must write the Erase Resume command.
The Erase Resume command is a one-bus cycle command. The only valid commands while
erase is suspended are Read Status Register, Product ID Entry, CFI Query, Program, Program Resume, Erase Resume, Sector Softlock/Hardlock, and Sector Unlock.
4.11
Program Suspend/Program Resume
The Program Suspend command allows the system to interrupt a programming operation and
then read data from a different word within the memory. After the Program Suspend command
is given, the device requires a maximum of 10 µs to suspend the programming operation. After
the programming operation has been suspended, the system can then read from any other
word within the device. An address is not required during the program suspend operation. To
resume the programming operation, the system must write the Program Resume command.
The program suspend and resume are one-bus cycle commands. The command sequence for
the erase suspend and program suspend are the same, and the command sequence for the
erase resume and program resume are the same. Read, Read Status Register, Product ID
Entry, Program Resume are valid commands during a Program Suspend.
4.12
Product Identification
The product identification mode identifies the device and manufacturer as Atmel®. It may be
accessed by a software operation. For details, see “Operating Modes” on page 21.
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AT49BV640D(T)
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AT49BV640D(T)
4.13
128-bit Protection Register
The AT49BV640D(T) contains a 128-bit register that can be used for security purposes in system design. The protection register is divided into two 64-bit blocks. The two blocks are
designated as block A and block B. The data in block A is non-changeable and is programmed
at the factory with a unique number. The data in block B is programmed by the user and can
be locked out such that data in the sector cannot be reprogrammed. To program block B in the
protection register, the two-bus cycle Program Protection Register command must be used as
shown in the “Command Definition Table” on page 15. To lock out block B, the two-bus cycle
Lock Protection Register command must be used as shown in the “Command Definition
Table”. Data bit D1 must be zero during the second bus cycle. To determine whether block B
is locked out, use the status of block B protection command. If data bit D1 is zero, block B is
locked. If data bit D1 is one, block B can be reprogrammed. Please see the “Protection Register Addressing Table” on page 16 for the address locations in the protection register. To read
the protection register, the Product ID Entry command is given followed by a normal read
operation from an address within the protection register. After determining whether block B is
protected or not, or reading the protection register, the Read command must be given to return
to the read mode.
4.14
Common Flash Interface (CFI)
CFI is a published, standardized data structure that may be read from a flash device. CFI
allows system software to query the installed device to determine the configurations, various
electrical and timing parameters, and functions supported by the device. CFI is used to allow
the system to learn how to interface to the flash device most optimally. The two primary benefits of using CFI are ease of upgrading and second source availability. The command to enter
the CFI Query mode is a one-bus cycle command which requires writing data 98h to any
address. The CFI Query command can be written when the device is ready to read data or can
also be written when the part is in the product ID mode. Once in the CFI Query mode, the system can read CFI data at the addresses given in “Common Flash Interface Definition Table”
on page 26. To return to the read mode, the read command should be issued.
4.15
Hardware Data Protection
Hardware features protect against inadvertent programs to the AT49BV640D(T) in the following ways: (a) VCC sense: if VCC is below 1.8V (typical), the device is reset and the program and
erase functions are inhibited. (b) Program inhibit: holding any one of OE low, CE high or WE
high inhibits program cycles. (c) Program inhibit: VPP is less than VILPP.
4.16
Input Levels
While operating with a 2.65V to 3.6V power supply, the address inputs and control inputs (OE,
CE and WE) may be driven from 0 to 5.5V without adversely affecting the operation of the
device. The I/O lines can be driven from 0 to VCCQ + 0.6V.
4.17
Output Levels
For the AT49BV640D(T), output high levels are equal to VCCQ - 0.1V (not VCC). For 2.65V to
3.6V output levels, VCCQ must be tied to VCC.
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3608C–FLASH–11/06
4.18
Word Program Flowchart
4.19
Word Program Procedure
Bus
Operation
Start
Write 40,
Any Address
Command
Program
Setup
Write
Data
Data = Data to program
Addr = Location to program
Read
None
Status register data: Toggle CE
or
OE to update status register
Idle
None
Check SR7
1 = WSM Ready
0 = WSM Busy
(Confirm)
Program
Suspend
Loop
Read-Status
Register
No
0
SR7 =
Suspend?
Ye s
1
Full Status
Check
(If Desired)
Data = 40
Addr = Any Address
Write
(Setup)
Write Data,
Word Address
Comments
Repeat for subsequent Word Program operations.
Full status register check can be done after each program, or
after a sequence of program operations.
Write FF after the last operation to set to the Read state.
Program
Complete
4.20
Full Status Check Flowchart
Read Status
Register
SR3 =
1
VP P Range
Error
4.21
Full Status Check Procedure
Bus
Operation
Command
Idle
None
Check SR3:
1 = VPP Error
Idle
None
Check SR4:
1 = Data Program Error
Idle
None
Check SR1:
1 = Sector locked; operation
aborted
0
SR4 =
1
Program
Error
0
SR1 =
1
Device
Protect Error
0
Comments
SR3 MUST be cleared before the Write State Machine allows
further program attempts.
If an error is detected, clear the status register before
continuing operations – only the Clear Status Register
command clears the status register error bits.
Program
Successful
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AT49BV640D(T)
4.22
Program Suspend/Resume Flowchart
4.23
Program Suspend/Resume Procedure
Bus
Operation
Start
Command
Comments
Write B0
Any Address
(Program Suspend)
Write
Program
Suspend
Data = B0
Addr = Any address
Write 70
Any Address
(Read Status)
Write
Read
Status
Data = 70
Addr = Any address
Read
None
Status register data: Toggle CE
or
OE to update status register
Addr = Any address
Idle
None
Check SR7
1 = WSM Ready
0 = WSM Busy
Idle
None
Check SR2
1 = Program suspended
0 = Program completed
Write
Read Array
Read
None
Write
Program
Resume
Read Status
Register
SR7 =
0
1
SR2 =
0
Program
Completed
1
Write FF
(Read Array)
Read
Data
Done
Reading
Write FF
No
Read
Data
Ye s
Write D0
Any Address
(Read
Array)
Data = FF
Addr = Any address
Read data from any word in the
memory
Data = D0
Addr = Any address
(Program Resume)
Program
Resumed
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4.24
Sector Erase Flowchart
4.25
Sector Erase Procedure
Bus
Operation
Start
Write 20,
Any Address
(Sector Erase)
Write D0,
(Erase Confirm)
Sector Address
Suspend
Erase
Loop
Read Status
Register
Command
Write
Sector
Erase
Setup
Write
Erase
Confirm
Data = D0
Addr = Sector to be erased (SA)
Read
None
Status register data: Toggle CE
or
OE to update status register data
Idle
None
Check SR7
1 = WSMS Ready
0 = WSMS Busy
No
Suspend
Erase
0
SR7 =
Full Erase
Status Check
(If Desired)
Repeat for subsequent sector erasures.
Full status register check can be done after each sector erase,
or after a sequence of sector erasures.
Write FF after the last operation to enter read mode.
Sector Erase
Complete
Full Erase Status Check Flowchart
SR3 =
4.27
Full Erase Status Check Procedure
Bus
Operation
Command
VP P Range
Error
Idle
None
Check SR3:
1 = VPP Range Error
Command
Sequence Error
Idle
None
Check SR4, SR5:
Both 1 = Command Sequence
Error
1
Sector Erase
Error
Idle
None
Check SR5:
1 = Sector Erase Error
1
Sector Locked
Error
Idle
None
Check SR1:
1 = Attempted erase of locked
sector; erase aborted.
Read Status
Register
1
0
SR4, SR5 =
1,1
0
SR5 =
0
SR1 =
0
Sector Erase
Successful
12
Data = 20
Addr = Any Address
Ye s
1
4.26
Comments
Comments
SR1, SR3 must be cleared before the Write State Machine
allows further erase attempts.
Only the Clear Status Register command clears SR1, SR3,
SR4, SR5.
If an error is detected, clear the status register before
attempting an erase retry or other error recovery.
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3608C–FLASH–11/06
AT49BV640D(T)
4.28
Erase Suspend/Resume Flowchart
4.29
Erase Suspend/Resume Procedure
Bus
Operation
Start
Command
Write B0,
Any Address
(Erase Suspend)
Write
Erase
Suspend
Data = B0
Addr = Any address
Write 70,
Any Address
(Read-Status)
Write
Read
Status
Data = 70
Addr = Any address
Read
None
Status register data: Toggle CE
or
OE to update status register
Addr = Any address
Idle
None
Check SR7
1 = WSM Ready
0 = WSM Busy
Idle
None
Check SR6
1 = Erase suspended
0 = Erase completed
Write
Read or
Program
Read or
Write
None
Write
Program
Resume
Read-Status
Register
SR7 =
0
1
SR6 =
0
Erase
Completed
1
Write FF
(Read Array)
Comments
ReadData
Done
Reading
0
Data = FF or 40
Addr = Any address
Read or program data from/to
sector other than the one being
erased
1
(Erase Resume)
Write D0,
Any Address
Write FF
Erase
Resumed
Read Array
Data
(Read-Array)
Data = D0
Addr = Any address
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4.30
Protection Register Programming
Flowchart
Write C0,
Any Address
Write PR
Address Data
SR7 =
Program
PR Setup
Data = C0
Addr = Any Address
(Confirm Data)
Write
Protection
Program
Data = Data to Program
Addr = Location to Program
Read
None
Status register data: Toggle CE
or
OE to update status register data
Idle
None
Check SR7
1 = WSMS Ready
0 = WSMS Busy
0
Full-Status
Check
(If Desired)
Program Protection Register operation addresses must be
within the protection register address space. Addresses
outside this space will return an error.
Repeat for subsequent programming operations.
Full status register check can be done after each program, or
after a sequence of program operations.
Write FF after the last operation to return to the Read mode.
Program
Complete
Full Status Check Flowchart
Read Status
Register Data
VP P Range Error
0
SR1, SR4 =
0, 1
1, 1
Register Locked;
Program Aborted
0
Program
Successful
14
4.33
Full Status Check Procedure
Bus
Operation
Command
Idle
None
Check SR1, SR3, SR4:
0,1,1 = VPP Range Error
Idle
None
Check SR1, SR3, SR4:
0,0,1 = Programming Error
Idle
None
Check SR1, SR3, SR4:
1, 0,1 = Sector locked; operation
aborted
Program Error
0
SR1, SR4 =
Comments
Write
1
1, 1
Command
(Program-Setup)
Read-Status
Register
SR3, SR4 =
Protection Register Programming
Procedure
Bus
Operation
Start
4.32
4.31
Comments
SR3 must be cleared before the Write State Machine allows
further program attempts.
Only the Clear Status Register command clears SR1, SR3,
SR4.
If an error is detected, clear the status register before
attempting a program retry or other error recovery.
AT49BV640D(T)
3608C–FLASH–11/06
AT49BV640D(T)
5. Command Definition Table
1st Bus Cycle
Bus
Cycles
Addr
Data
Read
1
XX
FF
Sector Erase
2
XX
2
Command Sequence
2nd Bus Cycle
Addr
Data
20
SA(2)
D0
XX
40/10
Addr
DIN
3
XX
E0
Addr0
DIN0
Erase/Program Suspend
1
XX
B0
Erase/Program Resume
1
XX
D0
1
XX
90
Sector Softlock
2
XX
60
SA(2)
01
Sector Hardlock
2
XX
60
SA(2)
2F
Sector Unlock
2
XX
60
SA(2)
D0
Read Status Register
2
XX
70
XX
DOUT(5)
Clear Status Register
1
XX
50
Program Protection Register (Block B)
2
XX
C0
Addr(6)
DIN
Lock Protection Register (Block B)
2
XX
C0
80
FFFD
Status of Protection Register (Block B)
2
XX
90
80
DOUT1(7)
CFI Query
1
XX
98
Word Program
Dual Word Program
Product ID Entry
Notes:
(3)
(4)
3rd Bus Cycle
Addr
Data
Addr1
DIN1
1. The DATA FORMAT shown for each bus cycle is as follows; I/O7 - I/O0 (Hex). I/O15 - I/O8 are don’t care. The ADDRESS FORMAT
shown for each bus cycle is as follows: A7 - A0 (Hex). Address A21 through A8 are don’t care.
2. SA = sector address. Any word address within a sector can be used to designate the sector address (see pages 17 - 20 for details).
3. This fast programming option enables the user to program two words in parallel only when VPP = 9.5V. The addresses, Addr0 and
Addr1, of the two words, DIN0 and DIN1, must only differ in address A0. This command should be used during manufacturing purposes only.
4. During the second bus cycle, the manufacturer code is read from address 000000H, the device code is read from address
000001H, and the data in the protection register is read from addresses 000081H - 000088H.
5. The status register bits are output on I/O7 - I/O0.
6. Any address within the user programmable protection register region. Address locations are shown on the “Protection Register
Addressing Table” on page 16.
7. If data bit D1 is “0”, block B is locked. If data bit D1 is “1”, block B can be reprogrammed.
15
3608C–FLASH–11/06
6. Absolute Maximum Ratings*
*NOTICE:
Temperature under Bias ................................ -55°C to +125°C
Storage Temperature ..................................... -65°C to +150°C
All Input Voltages Except VPP
(including NC Pins)
with Respect to Ground ...................................-0.6V to +6.25V
All Output Voltages
with Respect to Ground ...........................-0.6V to VCCQ + 0.6V
Stresses beyond those listed under “Absolute
Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and
functional operation of the device at these or any
other conditions beyond those indicated in the
operational sections of this specification is not
implied. Exposure to absolute maximum rating
conditions for extended periods may affect device
reliability.
VPP Input Voltage
with Respect to Ground .....................................-0.6V to 10.0V
7. Protection Register Addressing Table
Address
Use
Block
A8
A7
A6
A5
A4
A3
A2
A1
A0
81
Factory
A
0
1
0
0
0
0
0
0
1
82
Factory
A
0
1
0
0
0
0
0
1
0
83
Factory
A
0
1
0
0
0
0
0
1
1
84
Factory
A
0
1
0
0
0
0
1
0
0
85
User
B
0
1
0
0
0
0
1
0
1
86
User
B
0
1
0
0
0
0
1
1
0
87
User
B
0
1
0
0
0
0
1
1
1
User
B
0
1
0
0
0
1
0
0
0
88
Note:
16
All address lines not specified in the above table must be “0” when accessing the protection register, i.e., A21 - A8 = 0.
AT49BV640D(T)
3608C–FLASH–11/06
AT49BV640D(T)
8. Memory Organization –
AT49BV640D (Continued)
8. Memory Organization –
AT49BV640D
x16
x16
Sector
Size (Words)
Address Range
(A21 - A0)
SA35
32K
E0000 - E7FFF
SA36
32K
E8000 - EFFFF
SA37
32K
F0000 - F7FFF
SA38
32K
F8000 - FFFFF
SA39
32K
100000 - 107FFF
SA40
32K
108000 - 10FFFF
SA41
32K
110000 - 117FFF
SA42
32K
118000 - 11FFFF
SA43
32K
120000 - 127FFF
SA44
32K
128000 - 12FFFF
18000 - 1FFFF
SA45
32K
130000 - 137FFF
32K
20000 - 27FFF
SA46
32K
138000 - 13FFFF
SA12
32K
28000 - 2FFFF
SA47
32K
140000 - 147FFF
SA13
32K
30000 - 37FFF
SA48
32K
148000 - 14FFFF
SA14
32K
38000 - 3FFFF
SA49
32K
150000 - 157FFF
SA15
32K
40000 - 47FFF
SA50
32K
158000 - 15FFFF
SA16
32K
48000 - 4FFFF
SA51
32K
160000 - 167FFF
SA17
32K
50000 - 57FFF
SA52
32K
168000 - 16FFFF
SA18
32K
58000 - 5FFFF
SA53
32K
170000 - 177FFF
SA19
32K
60000 - 67FFF
SA54
32K
178000 - 17FFFF
SA20
32K
68000 - 6FFFF
SA55
32K
180000 - 187FFF
SA21
32K
70000 - 77FFF
SA56
32K
188000 - 18FFFF
SA22
32K
78000 - 7FFFF
SA57
32K
190000 - 197FFF
SA23
32K
80000 - 87FFF
SA58
32K
198000 - 19FFFF
SA24
32K
88000 - 8FFFF
SA59
32K
1A0000 - 1A7FFF
SA25
32K
90000 - 97FFF
SA60
32K
1A8000 - 1AFFFF
SA26
32K
98000 - 9FFFF
SA61
32K
1B0000 - 1B7FFF
SA27
32K
A0000 - A7FFF
SA62
32K
1B8000 - 1BFFFF
SA28
32K
A8000 - AFFFF
SA63
32K
1C0000 - 1C7FFF
SA29
32K
B0000 - B7FFF
SA64
32K
1C8000 - 1CFFFF
SA30
32K
B8000 - BFFFF
SA65
32K
1D0000 - 1D7FFF
SA31
32K
C0000 - C7FFF
SA66
32K
1D8000 - 1DFFFF
SA32
32K
C8000 - CFFFF
SA67
32K
1E0000 - 1E7FFF
SA33
32K
D0000 - D7FFF
SA68
32K
1E8000 - 1EFFFF
SA34
32K
D8000 - DFFFF
SA69
32K
1F0000 - 1F7FFF
SA70
32K
1F8000 - 1FFFFF
Sector
Size (Words)
Address Range
(A21 - A0)
SA0
4K
00000 - 00FFF
SA1
4K
01000 - 01FFF
SA2
4K
02000 - 02FFF
SA3
4K
03000 - 03FFF
SA4
4K
04000 - 04FFF
SA5
4K
05000 - 05FFF
SA6
4K
06000 - 06FFF
SA7
4K
07000 - 07FFF
SA8
32K
08000 - 0FFFF
SA9
32K
10000 - 17FFF
SA10
32K
SA11
17
3608C–FLASH–11/06
8. Memory Organization –
AT49BV640D (Continued)
18
8. Memory Organization –
AT49BV640D (Continued)
x16
x16
Sector
Size (Words)
Address Range
(A21 - A0)
Sector
Size (Words)
Address Range
(A21 - A0)
SA71
32K
200000 - 207FFF
SA103
32K
300000 - 307FFF
SA72
32K
208000 - 20FFFF
SA104
32K
308000 - 30FFFF
SA73
32K
210000 - 217FFF
SA105
32K
310000 - 317FFF
SA74
32K
218000 - 21FFFF
SA106
32K
318000 - 31FFFF
SA75
32K
220000 - 227FFF
SA107
32K
320000 - 327FFF
SA76
32K
228000 - 22FFFF
SA108
32K
328000 - 32FFFF
SA77
32K
230000 - 237FFF
SA109
32K
330000 - 337FFF
SA78
32K
238000 - 23FFFF
SA110
32K
338000 - 33FFFF
SA79
32K
240000 - 247FFF
SA111
32K
340000 - 347FFF
SA80
32K
248000 - 24FFFF
SA112
32K
348000 - 34FFFF
SA81
32K
250000 - 257FFF
SA113
32K
350000 - 357FFF
SA82
32K
258000 - 25FFFF
SA114
32K
358000 - 35FFFF
SA83
32K
260000 - 267FFF
SA115
32K
360000 - 367FFF
SA84
32K
268000 - 26FFFF
SA116
32K
368000 - 36FFFF
SA85
32K
270000 - 277FFF
SA117
32K
370000 - 377FFF
SA86
32K
278000 - 27FFFF
SA118
32K
378000 - 37FFFF
SA87
32K
280000 - 287FFF
SA119
32K
380000 - 387FFF
SA88
32K
288000 - 28FFFF
SA120
32K
388000 - 38FFFF
SA89
32K
290000 - 297FFF
SA121
32K
390000 - 397FFF
SA90
32K
298000 - 29FFFF
SA122
32K
398000 - 39FFFF
SA91
32K
2A0000 - 2A7FFF
SA123
32K
3A0000 - 3A7FFF
SA92
32K
2A8000 - 2AFFFF
SA124
32K
3A8000 - 3AFFFF
SA93
32K
2B0000 - 2B7FFF
SA125
32K
3B0000 - 3B7FFF
SA94
32K
2B8000 - 2BFFFF
SA126
32K
3B8000 - 3BFFFF
SA95
32K
2C0000 - 2C7FFF
SA127
32K
3C0000 - 3C7FFF
SA96
32K
2C8000 - 2CFFFF
SA128
32K
3C8000 - 3CFFFF
SA97
32K
2D0000 - 2D7FFF
SA129
32K
3D0000 - 3D7FFF
SA98
32K
2D8000 - 2DFFFF
SA130
32K
3D8000 - 3DFFFF
SA99
32K
2E0000 - 2E7FFF
SA131
32K
3E0000 - 3E7FFF
SA100
32K
2E8000 - 2EFFFF
SA132
32K
3E8000 - 3EFFFF
SA101
32K
2F0000 - 2F7FFF
SA133
32K
3F0000 - 3F7FFF
SA102
32K
2F8000 - 2FFFFF
SA134
32K
3F8000 - 3FFFFF
AT49BV640D(T)
3608C–FLASH–11/06
AT49BV640D(T)
9. Memory Organization –
AT49BV640DT (Continued)
9. Memory Organization –
AT49BV640DT
x16
x16
Sector
Size (Words)
Address Range
(A21 - A0)
SA0
32K
00000 - 07FFF
SA1
32K
08000 - 0FFFF
SA2
32K
10000 - 17FFF
SA3
32K
18000 - 1FFFF
Sector
Size (Words)
Address Range
(A21 - A0)
SA36
32K
120000 - 127FFF
SA37
32K
128000 - 12FFFF
SA38
32K
130000 - 137FFF
SA39
32K
138000 - 13FFFF
SA40
32K
140000 - 147FFF
SA41
32K
148000 - 14FFFF
SA42
32K
150000 - 157FFF
SA43
32K
158000 - 15FFFF
SA44
32K
160000 - 167FFF
SA45
32K
168000 - 16FFFF
SA46
32K
170000 - 177FFF
SA47
32K
178000 - 17FFFF
SA4
32K
20000 - 27FFF
SA5
32K
28000 - 2FFFF
SA6
32K
30000 - 37FFF
SA7
32K
38000 - 3FFFF
SA8
32K
40000 - 47FFF
SA9
32K
48000 - 4FFFF
SA10
32K
50000 - 57FFF
SA11
32K
58000 - 5FFFF
SA48
32K
180000 - 187FFF
SA12
32K
60000 - 67FFF
SA49
32K
188000 - 18FFFF
SA13
32K
68000 - 6FFFF
SA50
32K
190000 - 197FFF
SA14
32K
70000 - 77FFF
SA51
32K
198000 - 19FFFF
SA15
32K
78000 - 7FFFF
SA52
32K
1A0000 - 1A7FFF
SA16
32K
80000 - 87FFF
SA53
32K
1A8000 - 1AFFFF
SA17
32K
88000 - 8FFFF
SA54
32K
1B0000 - 1B7FFF
SA18
32K
90000 - 97FFF
SA55
32K
1B8000 - 1BFFFF
SA19
32K
98000 - 9FFFF
SA56
32K
1C0000 - 1C7FFF
SA20
32K
A0000 - A7FFF
SA57
32K
1C8000 - 1CFFFF
SA21
32K
A8000 - AFFFF
SA58
32K
1D0000 - 1D7FFF
SA22
32K
B0000 - B7FFF
SA59
32K
1D8000 - 1DFFFF
32K
1E0000 - 1E7FFF
SA23
32K
B8000 - BFFFF
SA60
SA24
32K
C0000 - C7FFF
SA61
32K
1E8000 - 1EFFFF
SA25
32K
C8000 - CFFFF
SA62
32K
1F0000 - 1F7FFF
SA26
32K
D0000 - D7FFF
SA63
32K
1F8000 - 1FFFFF
SA27
32K
D8000 - DFFFF
SA64
32K
200000 - 207FFF
SA28
32K
E0000 - E7FFF
SA65
32K
208000 - 20FFFF
SA29
32K
E8000 - EFFFF
SA66
32K
210000 - 217FFF
SA67
32K
218000 - 21FFFF
SA68
32K
220000 - 227FFF
SA69
32K
228000 - 22FFFF
SA70
32K
230000 - 237FFF
SA71
32K
238000 - 23FFFF
SA30
32K
F0000 - F7FFF
SA31
32K
F8000 - FFFFF
SA32
32K
100000 - 107FFF
SA33
32K
108000 - 10FFFF
SA34
32K
110000 - 117FFF
SA35
32K
118000 - 11FFFF
19
3608C–FLASH–11/06
9. Memory Organization –
AT49BV640DT (Continued)
20
9. Memory Organization –
AT49BV640DT (Continued)
x16
x16
Sector
Size (Words)
Address Range
(A21 - A0)
Sector
Size (Words)
Address Range
(A21 - A0)
SA72
32K
240000 - 247FFF
SA104
32K
340000 - 347FFF
SA73
32K
248000 - 24FFFF
SA105
32K
348000 - 34FFFF
SA74
32K
250000 - 257FFF
SA106
32K
350000 - 357FFF
SA75
32K
258000 - 25FFFF
SA107
32K
358000 - 35FFFF
SA76
32K
260000 - 267FFF
SA108
32K
360000 - 367FFF
SA77
32K
268000 - 26FFFF
SA109
32K
368000 - 36FFFF
SA78
32K
270000 - 277FFF
SA110
32K
370000 - 377FFF
SA79
32K
278000 - 27FFFF
SA111
32K
378000 - 37FFFF
SA80
32K
280000 - 287FFF
SA112
32K
380000 - 387FFF
SA81
32K
288000 - 28FFFF
SA113
32K
388000 - 38FFFF
SA82
32K
290000 - 297FFF
SA114
32K
390000 - 397FFF
SA83
32K
298000 -29FFFF
SA115
32K
398000 - 39FFFF
SA84
32K
2A0000 - 2A7FFF
SA116
32K
3A0000 - 3A7FFF
SA85
32K
2A8000 - 2AFFFF
SA117
32K
3A8000 - 3AFFFF
SA86
32K
2B0000 - 2B7FFF
SA118
32K
3B0000 - 3B7FFF
SA87
32K
2B8000 - 2BFFFF
SA119
32K
3B8000 - 3BFFFF
SA88
32K
2C0000 - 2C7FFF
SA120
32K
3C0000 - 3C7FFF
SA89
32K
2C8000 - 2CFFFF
SA121
32K
3C8000 - 3CFFFF
SA90
32K
2D0000 - 2D7FFF
SA122
32K
3D0000 - 3D7FFF
SA91
32K
2D8000 - 2DFFFF
SA123
32K
3D8000 - 3DFFFF
SA92
32K
2E0000 - 2E7FFF
SA124
32K
3E0000 - 3E7FFF
SA93
32K
2E8000 - 2EFFFF
SA125
32K
3E8000 - 3EFFFF
SA94
32K
2F0000 - 2F7FFF
SA126
32K
3F0000 - 3F7FFF
SA95
32K
2F8000 - 2FFFFF
SA127
4K
3F8000 - 3F8FFF
SA96
32K
300000 - 307FFF
SA128
4K
3F9000 - 3F9FFF
SA97
32K
308000 - 30FFFF
SA129
4K
3FA000 - 3FAFFF
SA98
32K
310000 - 317FFF
SA130
4K
3FB000 - 3FBFFF
SA99
32K
318000 - 31FFFF
SA131
4K
3FC000 - 3FCFFF
SA100
32K
320000 - 327FFF
SA132
4K
3FD000 - 3FDFFF
SA101
32K
328000 - 32FFFF
SA133
4K
3FE000 - 3FEFFF
SA102
32K
330000 - 337FFF
SA134
4K
3FF000 - 3FFFFF
SA103
32K
338000 - 33FFFF
AT49BV640D(T)
3608C–FLASH–11/06
AT49BV640D(T)
10. DC and AC Operating Range
AT49BV640D(T)-70
Operating Temperature (Case)
Industrial
-40°C - 85°C
VCC Power Supply
2.65V - 3.6V
11. Operating Modes
Mode
CE
OE
WE
RESET
VPP(1)
Ai
I/O
Read
VIL
VIL
VIH
VIH
X(2)
Ai
DOUT
Program/Erase(3)
VIL
VIH
VIL
VIH
VIHPP(4)
Ai
DIN
Standby/Program
Inhibit
VIH
X(2)
X
VIH
X
X
High Z
X
X
VIH
VIH
X
X
VIL
X
VIH
X
X
X
X
X
VILPP(5)
Output Disable
X
VIH
X
VIH
X
Reset
X
X
X
VIL
X
Program Inhibit
Product Identification
Software
Notes:
VIH
High Z
X
High Z
A0 = VIL, A1 - A21 = VIL
Manufacturer Code(6)
A0 = VIH, A1 - A21 = VIL
Device Code(6)
1. The VPP pin can be tied to VCC. For faster program operation, VPP can be set to 9.5V ± 0.5V.
2. X can be VIL or VIH.
3. Refer to AC programming waveforms on page 25.
4. VIHPP (min) = 1.65V.
5. VILPP (max) = 0.4V.
6. Manufacturer Code: 001FH; Device Code: 02DEH – AT49BV640D; 02DBH – AT49BV640DT
12. DC Characteristics
Symbol
Parameter
Condition
ILI
Input Load Current
ILO
Max
Units
VIN = 0V to VCC
2
µA
Output Leakage Current
VI/O = 0V to VCC
2
µA
ISB
VCC Standby Current CMOS
CE = VCCQ - 0.3V to VCC
15
25
µA
ICC(1)
VCC Active Read Current
f = 5 MHz; IOUT = 0 mA
10
15
mA
ICC1
VCC Programming Current
25
mA
IPP1
VPP Input Load Current
10
µA
VIL
Input Low Voltage
0.6
V
VIH
Input High Voltage
VOL
Output Low Voltage
IOL = 2.1 mA
VOH
Output High Voltage
IOH = -100 µA
Note:
Min
Typ
VCCQ - 0.6
V
0.45
VCCQ - 0.1
V
V
1. In the erase mode, ICC is 25 mA.
21
3608C–FLASH–11/06
13. Input Test Waveforms and Measurement Level
2.0V
AC
DRIVING
LEVELS
1.5V
AC
MEASUREMENT
LEVEL
0.6V
tR, tF < 5 ns
14. Output Test Load
VCCQ
1.8K
OUTPUT
PIN
1.3K
30 pF
15. Pin Capacitance
f = 1 MHz, T = 25°C(1)
CIN
COUT
Note:
22
Typ
Max
Units
Conditions
4
6
pF
VIN = 0V
8
12
pF
VOUT = 0V
1. This parameter is characterized and is not 100% tested.
AT49BV640D(T)
3608C–FLASH–11/06
AT49BV640D(T)
16. AC Read Characteristics
AT49BV640D(T)-70
Symbol
Parameter
tRC
Read Cycle Time
tACC
Access, Address to Data Valid
70
ns
tCE(1)
Access, CE to Data Valid
70
ns
(2)
Min
Max
70
Units
ns
OE to Data Valid
20
ns
tDF(3)(4)
CE, OE High to Data Float
25
ns
tOH
Output Hold from OE, CE or Address, whichever Occurs First
tRO
RESET to Output Delay
tOE
0
ns
100
ns
17. Asynchronous Read Cycle Waveform(1)(2)(3)(4)
tRC
ADDRESS VALID
A0 - A21
CE
tCE
tOE
OE
tDF
tOH
tACC
tRO
RESET
I/O0 - I/O15
Notes:
HIGH Z
OUTPUT
VALID
1. CE may be delayed up to tACC - tCE after the address transition without impact on tACC.
2. OE may be delayed up to tCE - tOE after the falling edge of CE without impact on tCE or by tACC - tOE after an address change
without impact on tACC.
3. tDF is specified from OE or CE, whichever occurs first (CL = 5 pF).
4. This parameter is characterized and is not 100% tested.
23
3608C–FLASH–11/06
18. AC Word Load Characteristics
Symbol
Parameter
Min
Max
Units
tAS, tOES
Address, OE Setup Time
20
ns
tAH
Address Hold Time
0
ns
tCS
Chip Select Setup Time
0
ns
tCH
Chip Select Hold Time
0
ns
tWP
Write Pulse Width (WE or CE)
25
ns
tWPH
Write Pulse Width High
15
ns
tDS
Data Setup Time
25
ns
tDH, tOEH
Data, OE Hold Time
0
ns
19. AC Word Load Waveforms
19.1
WE Controlled
19.2
CE Controlled
24
AT49BV640D(T)
3608C–FLASH–11/06
AT49BV640D(T)
20. Program Cycle Characteristics
Symbol
Parameter
tBP
Min
Typ
Max
Units
Word Programming Time
10
120
µs
tBPD
Word Programming Time in Dual Programming Mode
5
60
µs
tAS
Address Setup Time
20
ns
tAH
Address Hold Time
0
ns
tDS
Data Setup Time
25
ns
tDH
Data Hold Time
0
ns
tWP
Write Pulse Width
25
ns
tWPH
Write Pulse Width High
15
ns
tWC
Write Cycle Time
70
ns
tRP
Reset Pulse Width
500
ns
tSEC1
Sector Erase Cycle Time (4K Word Sectors)
0.1
2.0
seconds
tSEC2
Sector Erase Cycle Time (32K Word Sectors)
0.5
6.0
seconds
tES
Erase Suspend Time
15
µs
tPS
Program Suspend Time
10
µs
tERES
Delay between Erase Resume and Erase Suspend
500
µs
21. Program Cycle Waveforms
PROGRAM CYCLE
OE
(2)
CE
tBP
tWP
WE
tWPH
tDH
tAS
A0 - A21
XX
tAH
(1)
ADDRESS
tWC
I/O0 - I/O15
tDS
INPUT DATA
Note 3
22. Sector Erase Cycle Waveforms
OE
(2)
CE
tWP
tWPH
WE
tDH
tAS
A0 - A21
XX
tAH
(1)
Note 4
tWC
I/O0 - I/O15
tDS
20
WORD 0
Notes:
tSEC1/2
D0
WORD 1
1. Any address can be used to load data.
2. OE must be high only when WE and CE are both low.
3. The data can be 40H or 10H.
4. The address depends on what sector is to be erased.
25
3608C–FLASH–11/06
23. Common Flash Interface Definition Table
26
Address
AT49BV640DT
AT49BV640D
Comments
10h
0051h
0051h
“Q”
11h
0052h
0052h
“R”
12h
0059h
0059h
“Y”
13h
0003h
0003h
14h
0000h
0000h
15h
0041h
0041h
16h
0000h
0000h
17h
0000h
0000h
18h
0000h
0000h
19h
0000h
0000h
1Ah
0000h
0000h
1Bh
0027h
0027h
VCC min write/erase
1Ch
0036h
0036h
VCC max write/erase
1Dh
0090h
0090h
VPP min voltage
1Eh
00A0h
00A0h
VPP max voltage
1Fh
0004h
0004h
Typ word write – 10 µs
20h
0002h
0002h
Typ dual word program time – 5 µs
21h
0009h
0009h
Typ sector erase – 500 ms
22h
0000h
0000h
Typ chip erase – N/A
23h
0004h
0004h
Max word write/typ time
24h
0004h
0004h
Max dual word program time/typical time
25h
0003h
0003h
Max sector erase/typ sector erase
26h
0000h
0000h
Max chip erase/ typ chip erase – N/A
27h
0017h
0017h
Device size
28h
0001h
0001h
x16 device
29h
0000h
0000h
x16 device
2Ah
0002h
0002h
Maximum number of bytes in multiple byte write = 4
2Bh
0000h
0000h
Maximum number of bytes in multiple byte write = 4
2Ch
0002h
0002h
2 regions, x = 2
2Dh
007Eh
0007h
64K bytes, Y = 126 (Top); 8K bytes, Y = 7 (Bottom)
2Eh
0000h
0000h
64K bytes, Y = 126 (Top); 8K bytes, Y = 7 (Bottom)
2Fh
0000h
0020h
64K bytes, Z = 256 (Top); 8K bytes, Z = 32 (Bottom)
30h
0001h
0000h
64K bytes, Z = 256 (Top); 8K bytes, Z = 32 (Bottom)
31h
0007h
007Eh
8K bytes, Y = 7 (Top); 64K bytes, Y = 126 (Bottom)
32h
0000h
0000h
8K bytes, Y = 7 (Top); 64K bytes, Y = 126 (Bottom)
33h
0020h
0000h
8K bytes, Z = 32 (Top);64K bytes, Z = 256 (Bottom)
34h
0000h
0001h
8K bytes, Z = 32 (Top);64K bytes, Z = 256 (Bottom)
AT49BV640D(T)
3608C–FLASH–11/06
AT49BV640D(T)
23. Common Flash Interface Definition Table (Continued)
Address
AT49BV640DT
AT49BV640D
Comments
VENDOR SPECIFIC EXTENDED QUERY
41h
0050h
0050h
“P”
42h
0052h
0052h
“R”
43h
0049h
0049h
“I”
44h
0031h
0031h
Major version number, ASCII
45h
0030h
0030h
Minor version number, ASCII
46h
0086h
0086h
Bit 0 – chip erase supported, 0 – no, 1 – yes
Bit 1 – erase suspend supported, 0 – no, 1 – yes
Bit 2 – program suspend supported, 0 – no, 1 – yes
Bit 3 – simultaneous operations supported, 0 – no, 1 – yes
Bit 4 – burst mode read supported, 0 – no, 1 – yes
Bit 5 – page mode read supported, 0 – no, 1 – yes
Bit 6 – queued erase supported, 0 – no, 1 – yes
Bit 7 – protection bits supported, 0 – no, 1 – yes
47h
0000h
0001h
Bit 0 – top (“0”) or bottom (“1”) boot block device
Undefined bits are “0”
48h
0000h
0000h
Bit 0 – 4 word linear burst with wrap around, 0 – no, 1 – yes
Bit 1 – 8 word linear burst with wrap around, 0 – no, 1 – yes
Bit 2 – 16 word linear burst with wrap around, 0 – no, 1 – yes
Bit 3 – continuous burst, 0 – no, 1 – yes
Undefined bits are “0”
49h
0000h
0000h
Bit 0 – 4 word page, 0 – no, 1 – yes
Bit 1 – 8 word page, 0 – no, 1 – yes
Undefined bits are “0”
4Ah
0080h
0080h
Location of protection register lock byte, the section’s first byte
4Bh
0003h
0003h
# of bytes in the factory prog section of prot register – 2*n
4Ch
0003h
0003h
# of bytes in the user prog section of prot register – 2*n
27
3608C–FLASH–11/06
24. Ordering Information
24.1
Green Package (Pb/Halide-free/RoHS Compliant)
ICC (mA)
tACC
(ns)
Active
Standby
70
15
0.025
Ordering Code
Package
AT49BV640D-70CU
48C20
AT49BV640DT-70CU
48C20
Operation Range
Industrial
(-40° to 85° C)
Package Type
48C20
28
48-ball, Plastic Chip-size Ball Grid Array Package (CBGA)
AT49BV640D(T)
3608C–FLASH–11/06
AT49BV640D(T)
25. Packaging Information
25.1
48C20 – CBGA
E
A1 BALL ID
D
Top View
A1
A
E1
0.875 REF
e
A1 BALL CORNER
Side View
3.125 REF
COMMON DIMENSIONS
(Unit of Measure = mm)
A
SYMBOL
MIN
NOM
MAX
6.90
7.00
7.10
NOTE
B
E
C
D1
D
E1
D
E
5.25 TYP
9.90
D1
F
7
6
5
4
3
2
1
10.10
3.75 TYP
A
–
–
1.0
A1
0.21
–
–
e
8
10.00
b
Ø
0.75 BSC
0.35 TYP
Øb
Bottom View
01/8/04
R
2325 Orchard Parkway
San Jose, CA 95131
TITLE
48C20, 48-ball (8 x 6 Array),0.75 mm Pitch, 7.0 x 10.0 x 1.0 mm
Chip-scale Ball Grid Array Package (CBGA)
DRAWING NO.
48C20
REV.
A
29
3608C–FLASH–11/06
26. Revision History
30
Revision No.
History
Revision A – April 2006
•
Initial Release
Revision B – October 2006
•
Removed 56-lead TSOP Package.
Revision C – Nov. 2006
•
Fixed typo in the device description.
AT49BV640D(T)
3608C–FLASH–11/06
:
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3608C–FLASH–11/06