MCNIX MX69F1604C3TXBI-70

ADVANCED INFORMATION
MX69F1602/1604C3T/B
16M-BIT [X16] FLASH AND 2M-BIT/4M-BIT [X16] SRAM
MIXED MULTI CHIP PACKAGE MEMORY
FEATURES
• Supply voltage range: 2.7V to 3.6V
• Fast access time: Flash memory:70/90ns
SRAM memory:70/85ns
• Operation temperature range: -40 ~ 85°C
•
FLASH
•
•
• Word mode only
• VCCf=VCCQ=2.7V~3.6V for read, erase and program
operation
• VPP=12V for fast production programming
• Low power consumption
- 9mA typical active read current, f=5MHz
- 18mA typical program current (VPP=1.65~3.6V)
- 21mA typical erase current (VPP=1.65~3.6V)
- 7uA typical standby current under power saving mode
• Sector architecture
- Sector structure : 4Kword x 2 (boot sectors), 4Kword
x 6 (parameter sectors), 32Kword x 31 (main sectors)
- Top/Bottom Boot
• Auto Erase and Auto Program
- Automatically program and verify data at specified
address
- Auto sector erase at specified sector
• Automatic Suspend Enhance
•
•
•
•
•
- Word write suspend to read
- Sector erase suspend to word write
- Sector erase suspend to read register report
Automatic sector erase, word write and sector lock/
unlock configuration
100,000 minimum erase/program cycles
Boot Sector Architecture
- T = Top Boot Sector
- B = Bottom Boot Sector
Status Register feature for detection of program or
erase cycle completion
Data protection performance
- Sectors to be locked/unlocked
Common Flash Interface (CFI)
128-bit Protection Register
- 64-bit Unique Device Identifier
- 64-bit User-Programmable
Latch-up protected to 100mA from -1V to VCC+1V
SRAM
•
•
•
•
•
•
P/N:PM0954
MX69F1602C3T/B: 128K wordx16 Bit
MX69F1604C3T/B: 256K wordx16 Bit
70mA maximum active current
1uA typical standby current
Data retention supply voltage: 2.0V~3.6V
Byte data control : LBs(Q0 to Q7) and UBs(Q8 to Q15)
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MX69F1602/1604C3T/B
GENERAL DESCRIPTION
mand sequence to the CUI. A sector erase operation
erases one of the device's 32K-word sectors typically
within 1.0s, 4K-word sectors typically within 0.5s independent of other sectors. Each sector can be independently erased minimum 100,000 times. Sector erase
suspend mode allows system software to suspend sector erase to read or write data from any other sector.
The MXIC's mixed multi chip memory combines Flash
and SRAM into a single package. The mixed multi chip
memory operates 2.7 to 3.6V power supply to allow for
simple in-system operation.
The Flash memory of mixed multi chip memory manufactured with MXIC's advanced nonvolatile memory technology, the flash memory of mixed multi chip memory
is designed to be re-programmed and erased in system
or in standard EPROM programmers. The device offers
access times of 70ns/90ns, and 7uA typical standby
current.
Flash program automation allows program operation to
be executed using an industry-standard two-write command sequence to the CUI. Writing memory data is performed in word increments of the device's 32K-word sectors typically within 0.8s and 4K-word sectors typically
within 0.1s. Word program suspend mode enables the
system to read data or execute code from any other
memory array location.
Flash memories augment EPROM functionality with incircuit electrical erasure and programming and use a
command register to manage this functionality. The command register allows for 100% TTL level control inputs
and fixed power supply levels during erase and programming, while maintaining maximum EPROM compatibility.
The Flash features with individual sectors locking by
using a combination of thirty-nine sector lock-bits and
WP, to lock and unlock sectors.
The Flash status register indicates the status of the WSM
when the sector erase, word program or lock configuration operation is done.
Flash memory reliably stores memory contents even after 100,000 erase and program cycles. The cell is designed to optimize the erase and programming mechanisms. In addition, the combination of advanced tunnel
oxide processing and low internal electric fields for erase
and program operations produces reliable cycling.
The Flash power saving mode feature substantially reduces active current when the device is in static mode
(addresses not switching). In this mode, the typical ICCS
current is 7uA (CMOS) at 3.0V VCC. As CEf and R E SET are at VCC, ICC CMOS standby mode is enabled.
When RESET is at GND, the reset mode is enabled which
minimize power consumption and provide data write protection.
The highest degree of latch-up protection is achieved
with MXIC's proprietary non-epi process. Latch-up protection is proved for stresses up to 100 milliamperes on
address and data pin from -1V to VCC + 1V.
The Flash require a reset time (tPHQV) from RESET
switching high until outputs are valid. Similarly, the flash
has a wake time (tPHEL) from RESET-high until writes
to the CUI are recognized. With RESET at GND, the
WSM is reset and the status register is cleared.
The dedicated VPP pin gives complete data protection
when VPP< VPPLK.
The Flash contains both a Command User Interface (CUI)
and a Write State Machine (WSM). A Command User
Interface (CUI) serves as the interface between the system processor and internal operation of the device. A
valid command sequence written to the CUI initiates
device automation. An internal Write State Machine
(WSM) automatically executes the algorithms and timings necessary for erase, word write and sector lock/
unlock configuration operations.
The 2M-bit SRAM of MX69F1602C3T/B is organized as
128K-word by 16-bit. The 4M-bit SRAM of
MX69F1604C3T/B is organized 256K-word by 16-bit. The
advanced CMOS technology and circuit techniques provide both high speed and low power features of with a
typical CMOS standby current of 1uA and maximum
access time of 70ns/85ns in 3V operation.
The mixed multi chip memory is available in 11mm x
8mm FBGA Package to suit a variety of design applications.
Flash erase automation allows sector erase operation to
be executed using an industry-standard two-write com-
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MX69F1602/1604C3T/B
Feature Summary
Feature
MX69F1602/1604C3T/B
Vcc Operating Voltage
2.7~3.6V
Configuration
Flash
16M:1M Word x16bit
SRAM
MX69F1602C3T/B:128K Word x16bit
MX69F1604C3T/B:256K Word x16bit
Fast Access Time
Block Architecture
- 70 :
Flash/70ns, SRAM/70ns
- 90 :
Flash/90ns, SRAM/85ns
Flash
2 x 4K Word Boot
6 x 4K Word Parameter
31 x 32K Word Main
Address Pin
Flash
A0~A19
SRAM
MX69F1602C3T/B:A0~A16
MX69F1604C3T/B:A0~A17
Manufacture Code
Flash
00C2H
Device ID Code
Flash
MX69F1602/1604C3T=88C2H
MX69F1602/1604C3B=88C3H
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MX69F1602/1604C3T/B
PIN ASSIGNMENT
1.66-ball CSP for MX69F1602/1604C3T/B (Top View Balls Down, 11 x 8 x 1.4mm, Ball Pitch=0.8mm)
A
NC
A11
A15
A14
A13
A12
GNDf
VCCQ
B
A16
A8
A10
A9
Q15
WEs
Q14
Q7
C
WEf
NC
Q13
Q6
Q4
Q5
D
GNDs
RESET
Q12
CE2s
VCCs
VCCf
E
WP
VPP
A19
Q10
Q2
Q3
F
LBs
UBs
OEs
Q9
Q8
Q0
Q1
G
A18
A17
A7
A6
A3
A2
A1
CE1s
GNDf
OEf
NC
9
10
H
NC
NC
Q11
NC
NC
NC
A5
A4
A0
CEf
1
2
3
4
5
6
7
8
NC
NC
8.0 mm
NC
NC
11
12
11.0 mm
Notes:
1.To maintain compatibility with all JEDEC Variation B options for this ball location C6, this C6 land pad should be
connected directly to the land pad for ball G4 (A17).
PIN DESCRIPTION
SYMBOL
A0 to A16
A0 to A17
A17 to A19
A18 to A19
Q0 to Q15
CEf
CE1s
CE2s
OEf
OEs
PIN NAME
Address Inputs (Common) for
MX69F1602C3T/B
Address Inputs (Common) for
MX69F1604C3T/B
Address Input (Flash) for
MX69F1602C3T/B
Address Input (Flash) for
MX69F1604C3T/B
Data Inputs/Outputs (Common)
Chip Enable (Flash)
Chip Enable (SRAM)
Chip Enable (SRAM)
Output Enable (Flash)
Output Enable (SRAM)
SYMBOL
WEf
WEs
UBs
LBs
RESET
WP
N.C.
GND
VCCf
VCCs
VPP
VCCQ
PIN NAME
Write Enable (Flash)
Write Enable (SRAM)
Upper Byte Control (SRAM)
Lower Byte Control (SRAM)
Hardware Reset Pin/Deep Power
Down (Flash)
Write Protect
No Connection
Ground Pin (Common)
Power Supply (Flash, 2.7V~3.6V)
Power Supply (SRAM, 2.7V~3.6V)
Program/Erase Power Supply
(1.65V~3.6V or 11.4V~12.6V)
I/O Power Supply (Flash) tied to VCCf
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MX69F1602/1604C3T/B
BLOCK DIAGRAM for MX69F1602/1604C3T/B
VCCf VPP GND VCCQ
A0~A19
A0~A19
CEf
OEf
1MWx16bit (16M)
WEf
Q0 to Q15
Flash Memory
RESET
WP
Q0 to Q15
Vccs
GND
A0~A16/A0~A17
CE1s
CE2s
OEs
2M/4M bit
WEs
Static RAM
Q0 to Q15
UBs
LBs
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MX69F1602/1604C3T/B
DEVICE BUS OPERATIONS for MX69F1602/1604C3T/B
Notes CEf OEf
WEf CE1s CE2s OEs WEs
(1)
Full Standby
3,4
Flash Output Disable 3,4
Array
H
L
L
Read Query
L
X
H
L
L
X
H
H
H
from
Flash Configuration
L
Status
L
L
L
H
H
Register
Write to Flash
Reset
SRAM Output
5,7
3,4,6
3,4
L
X
H
H
X
X
L
X
X
(1)
(1)
H
X
X
L
H
X
X
L
H
X
X
L
H
X
X
L
H
X
X
L
H
X
X
L
H
X
X
L
H
X
X
L
L
H
Disable
Read from SRAM
Write to SRAM
H
H
X
X
X
X
L
L
H
H
LBs
UBs
Q0~
Q8~ RESET
Q7
Q15
X
X
X
X
High Z
High Z
H
X
X
X
X
High Z
High Z
H
X
X
X
X
Dout
Dout
H
X
X
X
X
Dout
Dout
H
X
X
X
X
ID(2)
ID(2)
H
X
X
X
X
Dout
Dout
H
X
X
X
X
Din
Din
H
X
X
X
X
High Z
High Z
L
H
H
X
X
High Z
High Z
H
X
X
H
H
L
H
L
L
Dout
Dout
H
H
L
High Z
Dout
H
L
H
Dout
High Z
H
L
L
Din
Din
H
H
L
X
Din
H
L
H
Din
X
H
H
L
Legend:
L=VIL, H=VIH, X at control pins=VIL or VIH. See "ELECTRIAL CHARACTERISTICS 1.DC Characteristics" for voltage levels.
Notes:
1. Do not apply CEf=VIL, CE1s=VIL and CE2s=VIH at a time.
2. ID=Device Identifier Code. See "Table 3. Configuration Code"
3. Outputs are dependent on a seperate device controlling bus output.
4. Modes of the flash and SRAM can be interleaved so that while one is disabled the other controls outputs.
5. To program or erase the lockable sectors hold WP at VIH.
6. RESET at GND ± 0.2V to ensure the lowest power consumption.
7. Refer to Table 2 for valid Din during a write operation.
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MX69F1602/1604C3T/B
Maximum Ratings" may cause permanent damage.
These are stress ratings only. Operation beyond the
"Operating Conditions" is not recommended and extended exposure beyond the "Operation Conditions" may
affect device reliability.
ELECTRICAL SPECIFICATIONS
ABSOLUTE MAXIMUM RATINGS
Operating Temperature
During Read, Sector Erase, Word
Write . . . . . . . . . . . . . . . . . . . . . . . . . -40oC to +85oC
Storage Temperature . . . . . . . . . . . . . .-65oC to +125oC
Voltage on Any Ball (except VCCf, VCCs, VCCQ and
VPP) with respect to GND . . . . . . . . .-0.5 V to VCC+0.5(1)
VPP Supply Voltage (for Sector Erase and Word Write)
with respect to GND . . . . . . . . . .-0.5V to +13.5V(1,2,4)
VCCf, VCCs and VCCQ Supply Voltage
with respect to GND. . . . . . . . . . . . . . . . .-0.2V to +4.0V(1)
Output Short Circuit Voltage . . . . . . . . . . . . .100mA(3)
1. Minimum DC voltage is -0.5V on input/output pins.
During transitions, this level may undershoot to -2.0V
for periods <20ns. Maximum DC voltage on input/output balls to VCCf/VCCs/VCCQ+0.5V which during transition; may overshoot to VCCf/VCCs/VCCQ+2.0V for
periods <20ns.
2. Maximum DC voltage on VPP may overshoot to
+14.0V for periods <20ns.
3. Output shorted for no more than one second. No more
than one output shorted at a time.
4. VPP voltage is normally 1.65V~3.6V. Connection to
supply of 11.4V~12.6V can only be done for 1000
cycles on the main sectors and 2500 cycles on the
parameter sectors during program/erase. VPP may
be connected to 12V for a total of 80 hours maximum.
WARNING: Stressing the device beyond the "Absolute
Operating Conditions (Temperature and VCC Operating Conditions)
Symbol
Parameter
Min.
Max.
TA
Unit
Notes
Operating Temperature
-40
+85
o
VCCf
Flash VCC Supply Voltage
2.7
3.6
V
VCCs
SRAM VCC Supply Voltage
2.7
3.6
V
VCCQ
Flash I/O Supply Voltage
2.7
3.6
V
1
VPP1
Supply Voltage
1.65
3.6
V
1
VPP2
Supply Voltage
11.4
12.6
V
1,2
Cycling
Sector Erase Cycling
C
100,000
1
2
NOTE:
1.VCCf and VCCQ must share the same supply.
2.Applying VPP=11.4~12.6V during a program/erase can only be done for a maximum of 1000 cycles on the main
sectors and 2500 cycles on the parameter sectors. VPP may be connected to 12V for a total of 80 hours maximum.
Capacitance (1) (TA=+25oC, f=1MHz)
Symbol
Parameter
Typ.
Max.
Unit
CIN
COUT
Test Condition
Input Capacitance
16
18
pF
VIN=0.0V
Output Capacitance
20
22
pF
VOUT=0.0V
NOTE:
1.Sampled, not 100% tested.
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MX69F1602/1604C3T/B
FLASH SECTOR STRUCTURE (MX69F1602/1604C3T)
Sector
Boot Sector 0
Boot Sector 1
Parameter Sector 0
Parameter Sector 1
Parameter Sector 2
Parameter Sector 3
Parameter Sector 4
Parameter Sector 5
Main Sector 0
Main Sector 1
Main Sector 2
Main Sector 3
Main Sector 4
Main Sector 5
Main Sector 6
Main Sector 7
Main Sector 8
Main Sector 9
Main Sector 10
Main Sector 11
Main Sector 12
Main Sector 13
Main Sector 14
Main Sector 15
Main Sector 16
Main Sector 17
Main Sector 18
Main Sector 19
Main Sector 20
Main Sector 21
Main Sector 22
Main Sector 23
Main Sector 24
Main Sector 25
Main Sector 26
Main Sector 27
Main Sector 28
Main Sector 29
Main Sector 30
Sector Size
4K Word
4K Word
4K Word
4K Word
4K Word
4K Word
4K Word
4K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
Address Range (h)
FF000 ~ FFFFF
FE000 ~ FEFFF
FD000 ~ FDFFF
FC000 ~ FCFFF
FB000 ~ FBFFF
FA000 ~ FAFFF
F9000 ~ F9FFF
F8000 ~ F8FFF
F0000 ~ F7FFF
E8000 ~ EFFFF
E0000 ~ E7FFF
D8000 ~ DFFFF
D0000 ~ D7FFF
C8000 ~ CFFFF
C0000 ~ C7FFF
B8000 ~ BFFFF
B0000 ~ B7FFF
A8000 ~ AFFFF
A0000 ~ A7FFF
98000 ~ 9FFFF
90000 ~ 97FFF
88000 ~ 8FFFF
80000 ~ 87FFF
78000 ~ 7FFFF
70000 ~ 77FFF
68000 ~ 6FFFF
60000 ~ 67FFF
58000 ~ 5FFFF
50000 ~ 57FFF
48000 ~ 4FFFF
40000 ~ 47FFF
38000 ~ 3FFFF
30000 ~ 37FFF
28000 ~ 2FFFF
20000 ~ 27FFF
18000 ~ 1FFFF
10000 ~ 17FFF
08000 ~ 0FFFF
00000 ~ 07FFF
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MX69F1602/1604C3T/B
FLASH SECTOR STRUCTURE (MX69F1602/1604C3B)
Sector
Boot Sector 0
Boot Sector 1
Parameter Sector 0
Parameter Sector 1
Parameter Sector 2
Parameter Sector 3
Parameter Sector 4
Parameter Sector 5
Main Sector 0
Main Sector 1
Main Sector 2
Main Sector 3
Main Sector 4
Main Sector 5
Main Sector 6
Main Sector 7
Main Sector 8
Main Sector 9
Main Sector 10
Main Sector 11
Main Sector 12
Main Sector 13
Main Sector 14
Main Sector 15
Main Sector 16
Main Sector 17
Main Sector 18
Main Sector 19
Main Sector 20
Main Sector 21
Main Sector 22
Main Sector 23
Main Sector 24
Main Sector 25
Main Sector 26
Main Sector 27
Main Sector 28
Main Sector 29
Main Sector 30
Sector Size
4K Word
4K Word
4K Word
4K Word
4K Word
4K Word
4K Word
4K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
32K Word
Address Range (h)
00000 ~ 00FFF
01000 ~ 01FFF
02000 ~ 02FFF
03000 ~ 03FFF
04000 ~ 04FFF
05000 ~ 05FFF
06000 ~ 06FFF
07000 ~ 07FFF
08000 ~ 0FFFF
10000 ~ 17FFF
18000 ~ 1FFFF
20000 ~ 27FFF
28000 ~ 2FFFF
30000 ~ 37FFF
38000 ~ 3FFFF
40000 ~ 47FFF
48000 ~ 4FFFF
50000 ~ 57FFF
58000 ~ 5FFFF
60000 ~ 67FFF
68000 ~ 6FFFF
70000 ~ 77FFF
78000 ~ 7FFFF
80000 ~ 87FFF
88000 ~ 8FFFF
90000 ~ 97FFF
98000 ~ 9FFFF
A0000 ~ A7FFF
A8000 ~ AFFFF
B0000 ~ B7FFF
B8000 ~ BFFFF
C0000 ~ C7FFF
C8000 ~ CFFFF
D0000 ~ D7FFF
D8000 ~ DFFFF
E0000 ~ E7FFF
E8000 ~ EFFFF
F0000 ~ F7FFF
F8000 ~ FFFFF
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MX69F1602/1604C3T/B
FLASH
2.0 BUS OPERATION
1.0 PRINCIPLES OF OPERATION
The local CPU reads and writes flash memory in-system. All bus cycles to or from the flash memory conform
to standard microprocessor bus cycles.
The product includes an on-chip WSM to manage sector erase, word write and lock-bit configuration functions.
After initial device power-up or return from reset mode
(see section on Bus Operations), the device defaults to
read array mode. Manipulation of external memory control pins allow array read, standby and output disable
operations.
2.1 Read
Status register and identifier codes can be accessed
through the CUI independent of the VPP voltage. All
functions associated with altering memory contents sector erase, word write, sector lock/unlock, status and
identifier codes - are accessed via the CUI and verified
through the status register.
The first task is to write the appropriate read mode command (Read Array, Read Configuration, Read Query or
Read Status Register) to the CUI. Upon initial device
power-up or after exit from reset, the device automatically resets to read array mode. In order to read data,
control pins set for CEf, OEf, WEf, RESET and WP must
be driven to active. CEf and OEf must be active to obtain data at the outputs. CEf is the device selection control. OEf is the data output (Q0-Q15) control and active
drives the selected memory data onto the I/O bus, WEf
must be VIH, RESET must be VIH, WP must be at VIL
or VIH.
Information can be read from any sector, configuration
codes or status register independent of the VPP voltage. RESET can be at VIH.
Commands are written using standard microprocessor
write timings. The CUI contents serve as input to the
WSM, which controls the sector erase, word write and
sector lock/unlock. The internal algorithms are regulated
by the WSM, including pulse repetition, internal verification and margining of data. Addresses and data are internally latched during write cycles. Address is latched
at falling edge of CEf and data latched at rising edge of
WEf. Writing the appropriate command outputs array data,
accesses the identifier codes or outputs status register
data.
2.2 Output Disable
With OEf at a logic-high level (VIH), the device outputs
are disabled. Output pins (Q0-Q15) are placed in a highimpedance state.
Interface software that initiates and polls progress of
sector erase, word write and sector lock/unlock can be
stored in any sector. This code is copied to and executed
from system RAM during flash memory updates. After
successful completion, reads are again possible via the
Read Array command. Sector erase suspend allows
system software to suspend a sector erase to read/write
data from/to sectors other than that which is suspend.
Word write suspend allows system software to suspend
a word write to read data from any other flash memory
array location.
2.3 Standby
CEf at a logic-high level (VIH) places the device in
standby mode which substantially reduces device power
consumption. Q0~Q15 outputs are placed in a high-impedance state independent of OEf. If deselected during
sector erase, word write or sector lock/unlock, the device continues functioning, and consuming active power
until the operation completes.
With the mechanism of sector lock, memory contents
cannot be altered due to noise or unwanted operation.
When RESET=VIH and VCCf<VLKO (lockout voltage),
any data write alteration can be failure. During read operation, if write VPP voltage is below VPPLK, then hardware level data protection is achieved. With CUI's twostep command sequence sector erase, word write or
sector lock/unlock, software level data protection is
achieved also.
2.4 Reset
As RESET=VIL, it initiates the reset mode. The device
enters reset/deep power down mode. However, the data
stored in the memory has to be sustained at least 100ns
in the read mode before the device becomes deselected
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MX69F1602/1604C3T/B
mands require the command and address within the device or sector within the device (Sector Lock) to be
locked. The Clear Sector Lock-Bits command requires
the command and address within the device.
and output high impedance state.
In read modes, RESET-low deselects the memory,
places output drivers in a high-impedance state and turns
off all internal circuits. RESET must be held low for a
minimum of 100ns. Time tPHQV is required after return
from reset mode until initial memory access outputs are
valid. After this wake-up interval tPHEL or tPHWL, normal operation is restored. The CUI is reset to read array
mode and status register is set to 80H. Sector lock bit is
set at lock status.
The CUI does not occupy an addressable memory location. It is written when WEf and CEf are active (whichever goes high first). The address and data needed to
execute a command are latched on the rising edge of
WEf or CEf. Standard microprocessor write timings are
used.
During sector erase, word write or sector lock/unlock
modes, RESET-low will abort the operation. Memory contents being altered are no longer valid; the data may be
partially erased or written.
In addition, CUI will go into either array read mode or
erase/write interrupted mode. When power is up and the
device reset subsequently, it is necessary to read status register in order to assure the status of the device.
Recognizing status register (SR.7~0) will assure if the
device goes back to normal reset and enters array read
mode.
2.5 Read Configuration Codes
The read configuration codes operation outputs the manufacturer code, device code, sector lock configuration
codes, and the protection register. Using the manufacturer and device codes, the system CPU can automatically match the device with its proper algorithms. The
sector lock codes identify locked and unlocked sectors.
2.6 Write
Writing commands to the CUI enable reading of device
data and identifier codes. They also control inspection
and clearing of the status register. When VCCf=2.7V3.6V and VPP within VPP1 or VPP2 range, the CUI additionally controls sector erase, word write and sector
lock/unlock.
The Sector Erase command requires appropriate command data and an address within the sector to be erased.
The Full Chip Erase command requires appropriate command data and an address within the device. The Word
Write command requires the command and address of
the location to be written. Set Sector lock/unlock com-
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are disable during VPP<VPPLK. Placing VPP on VPP1/
2 enables successful sector erase, word write and sector lock/unlock.
3.0 COMMAND DEFINITIONS
The flash memory has four read modes: read array, read
configuration, read status, read query, and two write
modes: program, erase. These read modes are accessible independent of the VPP voltage. But write modes
Device operations are selected by writing specific commands into the CUI. Table 2 defines these commands.
Table 2. Command Definition (1)
Command
Bus
Notes
Cycles
Read Array
Read Configuration
First Bus Cycle
Operation Address
Second Bus Cycle
Data
Required
(1)
(2)
(3)
1
Write
X
FFH
Operation Address
Data
(1)
(2)
(3)
>2
2,4
Write
X
90H
Read
IA
ID
Read Query
2
2,7
Write
X
98H
Read
QA
QD
Read Status Register
2
3
Write
X
70H
Read
X
SRD
Clear Status Register
1
3
Write
X
50H
Sector Erase/Confirm
2
Write
X
20H
Write
SA
D0H
Word Write
2
Write
X
40H/10H
Write
WA
WD
Program/Erase Suspend
1
Write
X
B0H
Program/Erase Resume
1
Write
X
D0H
Sector Lock
2
Write
X
60H
Write
SA
01H
Sector Unlock
2
Write
X
60H
Write
SA
D0H
Lock-Down Sector
2
Write
X
60H
Write
SA
2FH
Protection Program
2
Write
X
C0H
Write
PA
PD
Lock Protection Register
2
Write
X
C0H
Write
PA
FFFD
2,5
6
Notes:
1. Bus operation are defined at page 6 and referred to AC Timing Waveform.
2. X=Any address within device.
IA=ID-Code Address (refer to Table 3).
ID=Data read from identifier code.
SA=Sector Address within the sector being erased.
WA=Address of memory location to be written.
WD=Data to be written at location WA.
PA=Program Address, PD=Program Data
QA=Query Address, QD=Query Data.
3. Data is latched from the rising edge of WEf or CEf (whichever goes high first)
SRD=Data read from status register, see Table 5 for description of the status register bits.
4. Following the Read Configuration codes command, read operation access manufacturer, device codes, sector
lock/unlock codes, see chapter 4.2.
5. Either 40H or 10H command is recognized by the WSM as word write setup.
6. The sector unlock operation simultaneously clear all sector lock.
7. Read Query Command is read for CFI query information.
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3.1 Read Array Command
3.3 Read Status Register Command
Upon initial device power-up and after exit from reset
mode, the device defaults to read array mode. This operation is also initiated by writing the Read Array command. The device remains enabled for reads until another command is written. Once the internal WSM has
started a sector erase, word write or sector lock configuration the device will not recognize the Read Array
command until the WSM completes its operation unless
the WSM is suspended via a Sector Erase Suspend or
Word Write Suspend command. If RESET=VIL device
is in read Read Array command mode, this read operation no longer requires VPP. The Read Array command
functions independently of the VPP voltage and RESET
can be VIH.
CUI writes read status command (70H). The status register may be read to determine when a sector erase,
word write or lock-bit configuration is complete and
whether the operation completed successfully. (refer to
table 5) It may be read at any time by writing the Read
Status Register command. After writing this command,
all subsequent read operations output data from the status register until another valid command is written. The
status register contents are latched on the falling edge
of CEf or OEf, whichever occurs last. CEf or OEf must
toggle to VIH before further reads to update the status
register latch. The Read Status Register command functions independently of the VPP voltage. RESET can be
VIH.
3.2 Read Configuration Codes Command
3.4 Clear Status Register Command
The configuration code operation is initiated by writing
the Read Configuration Codes command (90H). To return to read array mode, write the Read Array Command
(FFH). Following the command write, read cycles from
addresses shown in Table 3 retrieve the manufacturer,
device, sector lock configuration codes and the protection register(see Table 3 for configuration code values).
To terminate the operation, write another valid command.
Like the Read Array command, the Read Configuration
Codes command functions independently of the VPP
voltage and RESET can be VIH. Following the Read Configuration Codes command, the information is shown:
Status register bits SR.5, SR.4, SR.3 or SR.1 are set to
"1"s by the WSM and can only be reset by the Clear
Status Register command (50H). These bits indicate
various failure conditions (see Table 5). By allowing system software to reset these bits, several operations (such
as cumulatively erasing multiple sectors or writing several words in sequence) may be performed. The status
register may be polled to determine if an error occurred
during the sequence.
To clear the status register, the Clear Status Register
command (50H) is written on CUI. It functions independently of the applied VPP Voltage. RESET can be VIH.
This command is not functional during sector erase or
word write suspend modes.
Table 3. Configuration Code
Code
Manufacturer Code
Address
Data
(A19-A0)
(Q15-Q0)
00000H
00C2H
Device Code(Top/Bottom) 00001H
88C2/88C3H
Sector Lock Configuration XX002H
LocK
- Sector is unlocked
Q0=0
- Sector is locked
Q0=1
- Sector is locked-down
Q1=1
Protection Register Lock
80
PR-LK
Protection Register
81-88
PR
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should be checked. If word write error is detected, the
status register should be cleared. The internal WSM verify
only detects errors for "1"s that do not successfully write
to "0"s. The CUI remains in read status register mode
until it receives another command.
3.5 Sector Erase Command
Erase is executed one sector at a time and initiated by a
two-cycle command. A sector erase setup is first written (20H), followed by a sector erase confirm (D0H). This
command sequence requires appropriate sequencing and
an address within the sector to be erased. Sector preconditioning, erase, and verify are handled internally by
the WSM. After the two-cycle sector erase sequence is
written, the device automatically outputs status register
data when read (see Figure 8). The CPU can detect sector erase completion by analyzing the output data of the
status register bit SR.7.
Reliable word writes can only occur when
VCCf=2.7V~3.6V and VPP=VPP1/2. If VPP is not within
acceptable limits, the WSM doesn't execut the program
command. If word write is attempted while VPP<VPPLK,
status register bits SR.3 and SR.4 will be set to "1".
Successful word write requires for boot sector that WP
is VIH the corresponding sector lock-bit be cleared. In
parameter and main sectors case, it must be cleared
the corresponding sector lock-bit. If word write is attempted when the excepting above sector being clocked
conditions, SR.1 and SR.4 will be set to "1". Word write
is not functional.
When the sector erase is complete, status register bit
SR.5 should be checked. If a sector erase error is detected, the status register should be cleared before system software attempts corrective actions. The CUI remains in read status register mode until a new command is issued.
3.7 Sector Erase Suspend Command
This two-step command sequence of set-up followed by
execution ensures that sector contents are not accidentally erased. An invalid sector Erase command sequence
will result in both status register bits SR.4 and SR.5
being set to "1". Also, reliable sector erasure can only
occur when 2.7V~3.6V and VPP=VPP1/2. In the absence
of this high voltage, sector contents are protected against
erasure. If sector erase is attempted while VPP<VPPLK
SR.3 and SR.5 will be set to "1". To successfully erase
the boot sector, the corresponding sector lock-bit must
be clear first. In parameter and sectors case, it must be
cleared the corresponding sector lock-bit. If sector erase
is attempted when the excepting above sector being
locked conditions, SR.1 and SR.5 will be set to "1". Sector erase is not functional.
The Sector Erase Suspend command (50H) allows sector-erase interruption to read or word write data in another sector of memory. Once the sector erase process
starts, writing the Sector Erase Suspend command requests that the WSM suspend the sector erase sequence
at a predetermined point in the algorithm. The device
outputs status register data when read after the Sector
Erase Suspend command is written. Polling status register bits SR.7 and SR.6 can determine when the sector
erase operation has been suspended (both will be set to
"1"). Specification tWHRH2/tEHRH2 defines the sector
erase suspend latency.
When Sector Erase Suspend command is written to the
CUI, if sector erase was finished, the device would be
placed read array mode. Therefore, after Sector Erase
Suspend command is written to the CUI, Read Status
Register command (70H) has to be written to CUI, then
status register bit SR.6 should be checked if/when the
device is in suspend mode.
3.6 Word Write Command
Word write is executed by a two-cycle command sequence. Word write setup (standard 40H or alternate 10H)
is written, followed by a second write that specifies the
address and data. The WSM then takes over, controlling
the word write and write verify algorithms internally. After the word write sequence is written, the device automatically outputs status register data when read (see
Figure 6). The CPU can detect the completion of the
word write event by analyzing the status register bit SR.7.
At this point, a Read Array command can be written to
read data from sectors other than that which is suspended. A Word Write commands sequence can also be
issued during erase suspend to program data in other
sectors. Using the Word Write Suspend command (see
Section 4.9), a word write operation can also be suspended. During a word write operation with sector erase
suspended, status register bit SR.7 will return to "0".
When word write is complete, status register bit SR.4
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is suspended are Read Status Register Read Configuration, Read Query and Word Write Resume. After Word
Write Resume command is written to the flash memory,
the WSM will continue the Word write process. Status
register bits SR.2 and SR.7 will automatically be cleared.
After the Word Write Resume command is written, the
device automatically outputs status register data when
read (see Figure 7). VPP must remain at VPP1/2 while
in word write suspend mode. RESET must also remain
at VIH (the same RESET level used for word write).
However, SR.6 will remain "1" to indicate sector erase
suspend status.
The only other valid commands while sector erase is
suspended are Read Status Register, Read Configuration, Read Query, Program Setup, Program Resume,
Sector Lock, Sector Unlock, Sector Lock-Down and sector erase Resume. After a Sector Erase Resume command is written to the flash memory, the WSM will continue the sector erase process. Status register bits SR.6
and SR.7 will automatically be cleared. After the Erase
Resume command is written, the device automatically
outputs status register data when read (see Figure 9).
VPP must remain at VPP1/2 while sector erase is suspended. RESET must also remain at VIH (the same
RESET level used for sector erase). Sector cannot resume until word write operations initiated during sector
erase suspend has completed.
If the time between writing the Word Write Resume command and writing the Word Write Suspend command is
short and both commands are written repeatedly, a longer
time is required than standard word write until the completion of the operation.
If the time between writing the Sector Erase Resume
command and writing the Sector Erase Suspend command is shorter than 15ms and both commands are written repeatedly, a longer time is required than standard
sector erase until the completion of the operation.
3.8 Word Write Suspend Command
The Word Write Suspend command allows word write
interruption to read data in other flash memory locations.
Once the word write process starts, writing the Word
Write Suspend command requests that the WSM suspend the Word write sequence at a predetermined point
in the algorithm. The device continues to output status
register data when read after the Word Write Suspend
command is written. Polling status register bits SR.7 and
SR.2 can determine when the word write operation has
been suspended (both will be set to "1"). Specification
tWHRH1/tEHRH1 defines the word write suspend latency.
When Word Write Suspend command write to the CUI, if
word write was finished, the device places read array
mode. Therefore, after Word Write Suspend command
write to the CUI, Read Status Register command (70H)
has to be written to CUI, then status register bit SR.2
should be checked for if/when the device is in suspend
mode.
At this point, a Read Array command can be written to
read data from locations other than that which is suspended. The only other valid commands while word write
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3.9 Sector Lock/Unlock /Lockdown Command
3.9.4 Read Sector Lock Status
3.9.1 Sector Locked State
The lock status of every sector can be read through
Read Configuration mode. To enter this mode, first command write 90H to the device. The subsequent reads at
sector address +00002 will output the lock status of this
sector. The lock status can be read from the lowest two
output pins Q0 and Q1. Q0 indicates the sector lock/
unlock status and set by the lock command and cleared
by the unlock command. When entering lock-down, the
lock status is automatically set. Q1 indicates lock-down
status and is set by the lock-down command. It cannot
be further cleared by software, only by device reset or
power-down.
The default status of all sectors upon power-up or reset
is locked. Any attempt on program or erase operations
will result in an error on bit SR.1 of a locked sector. The
status of a locked sector can be changed to unlocked or
lock-down using software commands. An unlocked sector can be locked by writing the sector lock command
sequence, 60H followed by 01H.
3.9.2 Sector Unlocked State
An unlocked sector can be programmed or erased. All
unlocked sector return to the locked state when the device is either reset or powered down. The status of an
unlocked sector can be changed to locked or lockeddown using software commands. A locked sector can
be unlocked by writing unlock command sequence, 60H
followed by D0H.
Sector Lock Configuration Table
Lock Status
Sector is unlocked
Sector is locked
Sector is locked-down
Data
Q0=0
Q0=1
Q1=1
3.9.3 Sector Locked-Down State
Sectors which are locked-down are protected from program and erase operation; however, the protection status of these sectors cannot be changed using software
commands alone. Any sector locked or unlocked can be
locked-down by writing the lock-down command sequence, 60H followed by 2FH. When the device is reset
or powered down, the locked-down sectors will revert to
the locked state.
The status of WP will determine the function of sector
lock-down and is summarized is followed:
WP
WP=0
WP=1
Sector Lock-down Description
- sectors are protected from program, erase,
and lock status changes
- the sector lock-down function is disabled
- an individual lock-down sector can be unlocked and relocked via software command.
Once WP goes low, sectors that previously
locked-down returns to lock-down state
regardless of any changes when WP was
high.
In addition, sector lock-down is cleared only when the
device is reset or powered down.
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sector is being placed in erase suspend, the locking status bits will be changed immediately, but when the erase
is resumed, the erase operation will complete.
3.9.5 Sector Locking while Erase Suspend
The sector lock status can be performed during an erase
suspend by using standard locking command sequences
to unlock, lock, or lock-down a sector.
Locking operation cannot be performed during a program
suspend.
In order to change sector locking during an erase operation, the write erase suspend command (B0H) is placed
first; then check the status register until it is shown that
the actual erase operation has been suspended. Subsequent writing the desired lock command sequence to a
sector and the lock status will be changed. When completing any desired lock, read or program operation, resume the erase operation with the Erase Resume Command (D0H).
3.9.6 Status Register Error Checking
The operation of locking system for this device can be
used the term "state (X,Y,Z)" to specify locking status,
where X=value of WP, Y=bit Q1 of the sector lock status
register, and Z=bit Q0 of the sector lock status register.
Q0 indicates if a sector is locked (1) or unlocked (0). Q1
indicates if a sector has been locked-down(1) or not (0).
If a sector is locked or locked-down during the same
Table 4. Sector Locking State Transitions
WP
Current State
Erase/Prog.
(X, Y, Z)=
Operation if
Lock Command Input Result (Next State)
(X, Y, Z)=
Q1
Q0
Name
Enable ?
Lock
Unlock
Lock-Down
0
0
0
Unlocked
Yes
(001)
Unchanged
(011)
0
0
1
Locked (default)
No
Unchanged
(000)
(011)
0
1
1
Locked-Down
No
Unchanged
Unchanged
Unchanged
1
0
0
Unlocked
Yes
(101)
Unchanged
(111)
1
0
1
Locked
No
Unchanged
(100)
(111)
1
1
0
Lock-Down Disabled
Yes
(111)
Unchanged
(111)
1
1
1
Lock-Down Disabled
No
Unchanged
(110)
Unchanged
Note:
At power-up or device reset, all sectors default to locked state (001) (if WP=0).
Holding WP=0 is the recommended default.
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MX69F1602/1604C3T/B
Table 5. Status Register Definition
WSMS
SESS
ES
PS
VPPS
PSS
SLS
R
7
6
5
4
3
2
1
0
NOTES:
Check WSM bit first to determine word program or sector Erase completion, before checking Program or Erase
Status bits.
SR.7 = WRITE STATE MACHINE STATUS (WSMS)
1 = Ready
0 = Busy
When Sector Erase Suspend is issued, WSM halts execution and sets both WSMS and SESS bits to "1". SESS
bit remains set to "1" until an Sector Erase Resume
command is issued.
SR.6 = SECTOR ERASE SUSPEND STATUS (SESS)
1 = Sector ERASE Suspended
0 = Sector Erase in Progress/Completed
SR.5 = ERASE STATUS (ES)
1 = Error in Programming
0 = Successful Sector Erase or Clear Sector LockBits
When this bit (SR.5) is set to "1", it means WSM is
unable to verify successful sector erasure.
SR.4 = PROGRAM STATUS (PS)
1 = Error in Programming
0 = Successful Programming
When this bit is set to "1", WSM has attempted but failed
to program a word.
SR.3 = VPP STATUS (VPPS)
1 = VPP Low Detect, Operation Abort
0 = VPP OK
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.
SR.3 bit is not guaranteed to report accurate feedback
between VPPLK and VPP1 min.
SR.2 = PROGRAM SUSPEND STATUS (PSS)
1 = Program Suspended
0 = Program in Progress/Completed
When program suspend is issued, WSM halts the execution and sets both WSMS and PSS bits to "1". SR.2
remains set to "1" until a Program Resume command is
issued.
SR.1 = SECTOR LOCK STATUS (SLS)
1 =Program/Erase attempted an 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.
SR.0 = RESERVED FOR FUTURE ENHANCEMENTS
(R)
SR. 0 is reserved for future use and should be masked
out when polling the status register.
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read cycles from addresses shown in Table 6 will retrieve the specified information. To return to read array
mode, write the Read Array Command (FFH).
4.0 128-Bit Protection Register
The 128 bits of protection register are divided into two
64-bit segments. One of the segments is programmed
at MXIC side with unique 64-bit number; where changes
are forbidden. The other segment is left empty for customer to program. Once the customer segment is programmed, it can be locked to prevent further reprogramming.
Two-cycle Protection Program Command is used to program protection register bits. The 64-bit number is programmed 16 bits at a time. First, write C0H Protection
Program Setup command. The next write to the device
will latch in address and data and program the specified
location. The allowable address are also shown in Table
6. Refer to Figure 11 for the Protection Register Programming Flowchart.
4.1 Protection Register Read & Programming
Any attempt to address Protection Program command
onto undefined protection register address space will
result in a Status Register error (SR.4 set to "1"). In
addition, attempting to program to a previously locked
protection register segment will result in a status register error (SR.4=1, SR.1=1).
The protection register is read in the configuration read
mode, which follows the stated Command Bus Definitions.
The device is switched to this read mode by writing the
Read Configuration command (90H). Once in this mode,
Table 6. Word-Wide Protection Register Addressing
Word
Lock
0
1
2
3
4
5
6
7
User
Both
Factory
Factory
Factory
Factory
Customer
Customer
Customer
Customer
A7
1
1
1
1
1
1
1
1
1
A6
0
0
0
0
0
0
0
0
0
A5
0
0
0
0
0
0
0
0
0
A4
0
0
0
0
0
0
0
0
0
A3
0
0
0
0
0
0
0
0
1
A2
0
0
0
0
1
1
1
1
0
A1
0
0
1
1
0
0
1
1
0
A0
0
1
0
1
0
1
0
1
0
Table 7. Protection Register Memory Map
4.2 Protection Register Locking
The user-programmable segment of the protection register is lockable by programming Bit 1 of the PR-Lock
location to 0. Bit 0 of this location is programmed to 0 at
MXIC to protect the unique device number. This bit is
set using the protection program command to program
"FFFD" to PR-LOCK location. After these bits have been
programmed, no further changes can be made to the
value stored in the protection register. Protection Program command to a locked section will result in a status
register error (Program Error bit SR.4 and Lock Error bit
SR.1 will be set to 1). Protection register lockout state is
not reversible.
Protection Register
Bit Address
88H~85H
84H~81H
80H(Bit0 & Bit1)
Purpose
4 words User Program
Register
4 words Factory Program
Register
Protection Register Lock
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MX69F1602/1604C3T/B
AC Input/Output Test Conditions
VCCQ
TEST POINTS
Input VCCQ/2
VCCQ/2 Output
0.0
Note:AC test inputs are driven at VCCQ/2 for a Logic "1" and 0.0V for a Logic "0".
Figure 1. Transient Input/Output Reference Waveform
Figure 2. SWITCHING TEST CIRCUITS
DEVICE UNDER
TEST
TEST SPECIFICATIONS
Test Condition
70
90
Output Load
1 TTL gate
Output Load Capacitance, CL 30
100
(including jig capacitance)
Input Rise and Fall Times
5
Input Pulse Levels
0.0-3.0
Input timing measurement
1.5
reference levels
Output timing measurement
1.5
reference levels
2.7K ohm
3.3V
CL
6.2K ohm
DIODES=IN3064
OR EQUIVALENT
Unit
pF
ns
V
V
V
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AC Characteristic -- Read Only Operation (1)
-70
Notes
Min.
-90
Sym.
Parameter
Max.
tAVAV
Read Cycle Time
tAVQV
Address to Output Delay
tELQV
CEf to Output Delay
tGLQV
OEf to Output Delay
tPHQV
RESET to Output Delay
tELQX
CEf to Output in Low Z
3
0
0
ns
tGLQX
OEf to Output in Low Z
3
0
0
ns
tEHQZ
CEf to Output in High Z
3
20
20
ns
tGHQZ
OEf to Output in High Z
3
20
20
ns
tOH
Output Hold from Address,
3
70
Min.
Max.
90
Unit
ns
70
90
ns
2
70
90
ns
2
20
30
ns
150
150
ns
0
0
ns
CEf, or OEf Change,
Whichever Occurs First
Notes:
1. See AC Waveform: Read Operations at Figure 3.
2. OEf may be delayed up to tELQV-tGLQV after the falling edge of CEf without impact on tELQV.
3. Sampled, but not 100% tested.
4. See test Configuration.
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Figure 3. READ-ONLY OPERATION AC WAVEFORM
Addresses(A)
Device and
Address Selection
VIH
Data
Valid
Standby
Address Stable
VIL
tAVAV
CEf (E)
VIH
VIL
tEHQZ
OEf (G)
VIH
VIL
tGHQZ
WEf (W)
VIH
tGLQV
VIL
tOH
tGLQX
tELQV
DATA VOH
(D/Q) VOL
tELQX
High Z
Valid Output
High Z
tAVQV
RESET (P)
VIH
tPHQV
VIL
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MX69F1602/1604C3T/B
AC Characteristic -- Write Operation
Note
-70
-90
Min.
Min.
Unit
150
150
ns
0
0
ns
Sym.
Parameter
tPHWL/tPHEL
RESET High Recovery to WEf(CEf) Going Low
tELWL/tWLEL
CEf(WEf) Setup to WEf(CEf) Going Low
tWLWH/tELEH
WEf(CEf) Pulse Width
4
45
60
ns
tDVWH/tDVEH
Data Setup to WEf(CEf) Going High
2
40
50
ns
tAVWH/tAVEH
Address Setup to WEf(CEf) Going High
2
50
60
ns
0
0
ns
tWHEH/tEHWH CEf(WEf) Hold Time from WEf(CEf) High
tWHDX/tEHDX
Data Hold Time from WEf(CEf) High
2
0
0
ns
tWHAX/tEHAX
Address Hold Time from WEf(CEf) High
2
0
0
ns
tWHWL/tEHEL
WEf(CEf) Pulse Width High
4
25
30
ns
tVPWH/tVPEH
VPP Setup to WEf(CEf) Going High
3
200
200
ns
tQVVL
VPP Hold from Valid SRD
3
0
0
ns
tBHWH/tBHEH
WP Setup to WEf(CEf)Going High
3
0
0
ns
tQVBL
WP Hold from Valid SRD
3
0
0
ns
tWHGL
WEf High to OEf Going Low
3
30
30
ns
Notes:
1. Write timing characteristics during erase suspend are the same as during write-only operations.
2. Refer to Table 4 for valid AIN or DIN.
3. Sampled, not 100% tested.
4. Write pulse width (tWP) is defined from CEf or WEf going low (whichever goes low last) to CEf or WEf going high
(whichever goes high first). Hence, tWP=tWLWH=tELEH=tWLEH=tELWH. Similarly, Write pulse width high (tWPH)
is defined from CEf or WEf going high (whichever goes high first) to CEf or WEf going low (whichever goes low
first). Hence, tWPH=tWHWL=tEHEL=tWHEL=tEHWL.
5. See Test Configuration.
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MX69F1602/1604C3T/B
Figure 4. WRITE AND ERASE OPERATION AC WAVEFORM
A
Address (A)
B
C
AIN
AIN
D
E
F
VIH
VIL
tAVWH
(tAVEH)
tWHAX
(tEHAX)
(Note 1)
VIH
CEf(WEf)[E(W)]
VIL
tELWL
(tWLEL)
tWHEH
(tEHWH)
VIH
OEf(G)
tWHWL
(tEHEL)
VIL
tWHGL
(Note 1)
Disable VIH
WEf,(CEf)[W(E)]
Enable VIL
tELEH
(tWLWH)
VIH High Z
DATA[D/Q]
tDVWH
(tEVEH)
tWHDX
(tEHDX)
DIN
DIN
VIL
Valid
SRD
DIN
tPHWL
(tPHEL)
VOH
RESET[P]
VOL
tQVBL
tBHWH
(tBHEH)
VIH
WP
VIL
tVPWH
(tVPEH)
tQVVL
VPPH2
VPPH1
VPP[V]
VPPLK
VIL
Notes:
1. CEf must be toggled low when reading Status Register Data. WEf must be inactive (high) when reading Status
Register Data.
A.VCCf Power-Up and Standby.
B.Write Program or Erase Setup Command.
C.Write Valid Address and Data (for Program) or Erase Confirm Command.
D.Automated Program or Erase Delay.
E.Read Status Register Data (SRD): reflects completed program/erase operation.
F.Write Read Array Command.
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MX69F1602/1604C3T/B
Erase and Program Timing (1)
Vpp
Symbol
Parameter
tBWPB
4-KW Parameter Sector
1.65V-3.6V
11.4V-12.6V
Note
Typ(1)
Max
Typ(1)
Max
Unit
2,3
0.10
0.30
0.03
0.12
s
2,3
0.8
2.4
0.24
1
s
Word Program Time
2,3
12
200
8
185
us
tWHQV2/
4-KW Parameter Sector
2,3
0.5
4
0.4
4.0
s
tEHQV2
Erase Time
tWHQV3/
32-KW Main Sector
2,3
1
5
0.6
5
s
tEHQV3
Erase Time
tWHRH1/
Program Suspend Latency
3
15
20
15
20
us
Erase Suspend Latency
3
15
20
15
20
us
Word Program Time
tBWMB
32-KW Main Sector
Word Program Time
tWHQV1/
tEHQV1
tEHRH1
tWHRH2/
tEHRH2
Notes:
1. Typical values measured at TA=+25°C and nominal voltage.
2. Excludes external system-level overhead.
3. Sampled, but not 100% tested.
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MX69F1602/1604C3T/B
Figure 5. RESET WAVEFORM
VIH
RESET (P)
tPHQV
tPHWL
tPHEL
VIL
tPLPH
(A) Reset during Read Mode
tPLRH
RESET (P)
Abort
Complete
tPHQV
tPHWL
tPHEL
VIH
VIL
tPLPH
(B) Reset during Program or Sector Erase, tPLPH < tPLRH
Abort
Complete
tPLRH
Deep
PowerDown
tPHQV
tPHWL
tPHEL
VIH
RESET (P)
VIL
tPLPH
(C) Reset Program or Sector Erase, tPLPH > tPLRH
AC Characteristic -- Under Reset Operation
Sym.
Parameter
VCCf=2.7V~3.6V
Min.
tPLPH
RESET Low to Reset during Read
Unit
Notes
ns
1,3
Max.
100
(If RESET is tied to VCCf, this specification is not applicable)
tPLRH1 RESET Low to Reset during Sector Erase
22
us
1,4
tPLRH2 RESET Low to Reset during Program
12
us
1,4
Notes:
1. See Section 3.4 for a full description of these conditions.
2. If tPLPH is < 100ns the device may still reset but this is not guaranteed.
3. If RESET is asserted while a sector erase or word program operation is not executing, the reset will complete
within 100ns.
4. Sampled, but not 100% tested.
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MX69F1602/1604C3T/B
DC Characteristics
VCCf
2.7V-3.6V
VCCQ
2.7V-3.6V
Note Typ.
Max.
1,2
±1
Sym.
Parameter
ILI
Input Load Current
ILO
Output Leakage
Current
VCC Standby Current
1,2
0.2
± 10
uA
1
7
15
uA
ICCD
VCC Power-Down
Current
1,2
7
15
uA
ICCR
VCC Read Current
1,2,3
9
18
mA
IPPD
1
0.2
5
uA
IPPR
VPP Deep PowerDown Current
VPP Read Current
1,4
ICCW+
IPPW
ICCE+
IPPE
ICCES
or
ICCWS
VIL
VIH
VOL
VCC+VPP Program
Current
VCC+VPP Erase
Current
VCC Program
or Erase Suspend
Current
Input Low Voltage
Input High Voltage
Output Low Voltage
2
50
18
10
21
16
7
±15
200
55
30
45
45
15
uA
uA
mA
mA
mA
mA
uA
-0.4
2.0
-0.1
VCCf*0.22V
VCCQ+0.3V
0.1
V
V
V
VOH
Output High Voltage
VPPLK
VPP1
VPP2
VLKO
VPP Lock-Out Voltage
VPP during Program/
Erase Operations
VCC Prog/Erase
Lock Voltage
VCCQ Prog/Erase
Lock Voltage
ICCS
VLKO2
1,4
1,4
1,4
VCCQ
-0.1V
6
6
6
1.65
11.4
1.5
Unit
uA
V
1.0
3.6
12.6
1.2
V
V
V
V
Test Conditions
VCCf=VCCf Max. ; VCCQ=VCCQ Max.
VIN=VCCQ or GND
VCCf=VCCf Max. ; VCCQ=VCCQ Max.
VIN=VCCQ or GND
VCCf=VCCf Max. ; CEf=RESET=VCCQ
or during Program/Erase Suspend
WP=VCCQ or GND
VCCf=VCCf Max. ; VCCQ=VCCQ Max
VIN=VCCQ or GND
RESET=GND±0.2V
VCCf=VCCf Max. ; VCCQ=VCCQ Max
OEf=VIH, CEf=VIL, f=5MHz,
IOUT=0mA, Inputs=VIL or VIH
RESET=GND±0.2V
VPP < VCCf
VPP < VCCf
VPP > VCCf
VPP=VPP1, Program in Progress
VPP=VPP2(12V), Program in Progress
VPP=VPP1, Erase in Progress
VPP=VPP2(12V), Erase in Progress
CEf=VCCf,
Program or Erase Suspend in Progress
VCCf=VCCf Min, VCCQ=VCCQ Min
IOL=100uA
VCCf=VCCf Min, VCCQ=VCCQ Min
IOH=-100uA
Complete Write Protection
V
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MX69F1602/1604C3T/B
Notes:
1. All currents are in RMS unless otherwise noted. Typical values at nominal VCCf, TA=+25°C.
2. The test conditions VCCf Max, VCCQ Max, VCCf Min, and VCCQ Min refer to the maximum or minimum VCCf or
VCCQ voltage listed at the top of each column.
3. Power Savings (Mode) reduces ICCR to approximately standby levels in static operation (CMOS inputs).
4. Sampled, but not 100% tested.
5. ICCES and ICCWS are specified with device de-selected. If device is read while in erase suspend, current draw is
sum of ICCES and ICCR. If the device is read while in program suspend, current draw is the sum of ICCWS and
ICCR.
6. Erase and Program are inhibited when VPP<VPPLK.
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MX69F1602/1604C3T/B
Figure 6. Automated Word Programming Flowchart
Bus
Command
Operation
Write
Program
Setup
Write
Program
Start
Write 40H
Data=40H
Data=Data to Program
Addr=Location to Program
Read
Status Register Data Toggle
CEf or OEf to Update
Status Register Data
Standby
Check SR.7
1=WSM Ready
0=WSM Busy
Repeat for subsequent programming operations.
SR full status check can be done after each program
or after a sequence of program operations.
Write FFH after the last program operation to reset
device to read array mode.
Program Address/Data
Read Status Register
SR.7=1 ?
Comments
No
Yes
Full Status
Check if Desired
Program Ccomplete
Bus
Command
Operation
Standby
FULL STATUS CHECK PROCEDURE
Read Status Register
Data(See Above)
SR.3=
1
Check SR.3
1=VPP Low Detect
Standby
Check SR.4
1=VPP Program Error
Standby
Check SR.1
1=Attempted Program to
Locked Sector-Program
Aborted
SR.3 MUST be cleared, if set during a program attempt, before further attempts are allowed by the Write
State Machine.
SR.4, SR.3, and SR.1 are only cleared by the Clear
Status Register Command, in cases where multiple
bytes are programmed before full status is checked.
If an error is detected, clear the status register before
attempting retry or other error recovery.
VPP Range Error
0
SR.4=
1
Programming Error
0
SR.1=
1
Comments
Attempted Program to
Locked Sector- Aborted
0
Program Successful
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MX69F1602/1604C3T/B
Figure 7. Program Suspend/Resume Flowchart
Bus
Command
Operation
Write
Program
Suspend
Write
Read Status
Start
Write B0H
Write 70H
Read
Read
Status Register
SR.7=
0
Standby
1
Stanby
SR.2=
0
Program Completed
Write
1
Read Array
Write FFH
Read
Read Array Data
Write
Done Reading
Program
Resume
Comments
Data=B0H
Addr=X
Data=70H
Addr=X
Status Register Data Toggle
CEf or OEf to Update
Status Register Data
Addr=X
Check SR.7
1=WSM Ready
0=WSM Busy
Check SR.2
1=Program Suspended
0=Program Completed
Data=FFH
Addr=X
Read array data from
sector other than the one
being programmed.
Data=D0H
Addr=X
No
Yes
Write D0H
Write FFH
Program Write Resumed
Read Array Data
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MX69F1602/1604C3T/B
Figure 8. Automated Sector Erase Flowchart
Bus
Command Comments
Operation
Write
Erase Setup Data=20H
Addr=Within Sector to Be
Erased
Write
Erase
Data=D0H
Confirm
Addr=Within Sector to Be
Erased
Read
Status Register Data Toggle
CEf or OEf to Update
Status Register Data
Standby
Check SR.7
1=WSM Ready
0=WSM Busy
Repeat for subsequent sector erasures.
Full status check can be done after each sector erase
or after a sequence of sector erasures.
Write FFH after the last write operation to reset device
to read array mode.
Start
Write 20H
Write D0H and
Sector Address
Read
Status Register
Suspend
Erase Loop
No
SR.7=
Yes
0
Suspend Erase
1
Full Status Check if Desired
Sector Erase Complete
FULL STATUS CHECK PROCEDURE
Bus
Command
Operation
Standby
Read Status Register
Data(See Above)
SR.3=
1
Check SR.3
1=VPP Low Detect
Standby
Check SR.4, 5
Both 1=Command
Sequence Error
Standby
Check SR.5
1=Sector Erase Error
Standby
Check SR.1
1=Attempted Erase of
Locked Sector- Erase
Aborted
SR.1 and SR.3 MUST be cleared, if set during an erase
attempt, before further attempts are allowed by the
Write State Machine.
SR.1,3,4,5 are only cleared by the Clear Status Register Command, in cases where multiple bytes are
erased before full status is checked.
If an error is detected, clear the status register before
attempting retry or other error recovery.
VPP Range Error
0
SR.4,5=
1
Command Sequence Error
0
SR.5=
1
Sector Erase Error
0
SR.1=
1
Comments
Attempted Erase of Locked
Sector - Aborted
0
Sector Erase Successful
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MX69F1602/1604C3T/B
Figure 9. Erase Suspend/Resume Flowchart
Bus
Command
Operation
Write
Erase
Suspend
Write
Read Status
Start
Write B0H
Write 70H
Read
Read
Status Register
SR.7=
Standby
0
1
Stanby
SR.6=
0
Erase Completed
Write
1
Read Array
Write FFH
Read
Read Array Data
Write
Done Reading
Erase
Resume
Comments
Data=B0H
Addr=X
Data=70H
Addr=X
Status Register Data Toggle
CEf or OEf to Update
Status Register Data
Addr=X
Check SR.7
1=WSM Ready
0=WSM Busy
Check SR.6
1=Erase Suspended
0=Erase Completed
Data=FFH
Addr=X
Read array data from
sector other than the one
being erased.
Data=D0H
Addr=X
No
Yes
Write D0H
Write FFH
Erase Write Resumed
Read Array Data
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MX69F1602/1604C3T/B
Figure 10. Locking Operations Flowchart
Bus
Command
Comments
Operation
Write
Config. Setup Data=60H
Addr=X
Write
Lock, unlock Data=01H (Sector Lock)
or Lockdown
D0H(Sector Unlock)
2FH(Sector Lockdown)
Addr=Within sector to lock
Write
Read Status Data=70H
(Optional) Register
Addr=X
Read
Status Register Register
(Optional)
Addr=X
Stanby
Check Status Register
(Optional)
80H=no error
30H=Lock Command
Sequence Error
Write
Read
Data=90H
(Optional) Configuration Addr=X
Read
Sector Lock Sector Lock Status Data
(Optional)
Status
Addr=Second addr of
sector
Stanby
Confirm Locking Change
on Q1, Q0 (See Sector
Locking State Table for
valid combinations.)
Start
Write 60H
(Configuration Setup)
Write
01H, D0H, or 2FH
Write 70H
(Read Status Register)
Lock Command
Sequence Error
Read Status Register
SR.4, SR.5=
1,1
0,0
Write 90H
(Read Configuration)
Read Sector Lock Status
Locking Change
Confirmed ?
No
Yes
Locking Change
Complete
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MX69F1602/1604C3T/B
Figure 11. Protection Register Programming Flowchart
Bus
Command
Operation
Write
Protection
Program
Setup
Write
Protection
Program
Read
Start
Write C0H
(Protection Reg. Program Setup)
Data=C0H
Data=Data to Program
Addr=Location to Program
Status Register Data Toggle
CEf or OEf to Update
Status Register Data
Standby
Check SR.7
1=WSM Ready
0=WSM Busy
Protection Program operations can only be addressed
within the protection register address space. Addresses
outside the defined space will return an error.
Repeat for subsequent programming operations.
SR Full Status Check can be done after each program
or after a sequence of program operations.
Write FFH after the last operation to reset device to
read array mode.
Write Protect. Register
Address/Data
Read Status Register
SR.7=1 ?
Comments
No
Yes
Full Status
Check if Desired
Program Ccomplete
FULL STATUS CHECK PROCEDURE
Read Status Register
Data(See Above)
SR.3, SR.4=
SR.1, SR.4=
SR.1, SR.4=
Bus
Command
Operation
Standby
1,1
SR.1, SR.3, SR.4
0
1
1 VPP Low
Standby
0
0
1 Prot. Reg.
Prog. Error
Stanby
1
0
1 Register
Locked:
Aborted
SR.3 MUST be cleared, if set during a program attempt, before further attempts are allowed by the Write
State Machine.
SR.1,3,4 are only cleared by the Clear Status Register Command, in cases of multiple protection register
program operations before full status is checked.
If an error is detected, clear the status register before
attempting retry or other error recovery.
VPP Range Error
0,1
Protection Register
programming Error
1,1
Attempted Program to
Locked Register Aborted
Comments
Program Successful
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MX69F1602/1604C3T/B
5.0 VPP Program and Erase Voltage
MX69F1602/1604C3T/B product provides in-system programming and erase in the 1.65V~3.6V of VPP range. In
addition, VPP pin on 12V provides fast production programming.
5.1 VPP Fast manufacturing Programming
When VPP is between 1.65V and 3.6V, all program and
erase current is drawn through the VCCf pin. If VPP is
driven by a logic signal, VIH=1.65V. That is, VPP must
remain above 1.65V to perform in-system flash update/
modifications. When VPP is connected to a 12V power
supply, the device draws program and erase current directly from the VPP pin.
5.2 Protection Under VPP<VPPLK
VPP can off additional hardware write protection. The
VPP programming voltage can be kept low for the absolute hardware protection of all sector in the flash device.
As VPP is below VPPLK, any program or erase operation will result in a error, prompting the corresponding
status register bit (SR.3) to be set.
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MX69F1602/1604C3T/B
The single cycle Query command is valid only when the
device is in the Read mode, including Erase Suspend,
Program Suspend, Standby mode, and Read ID mode;
however, it is ignored otherwise.
6.0 QUERY COMMAND AND COMMON FLASH
INTERFACE (CFI) MODE
MX69F1602/1604C3T/B is capable of operating in the
CFI mode. This mode allows the host system to determine the manufacturer of the device such as operating
parameters and configuration. Two commands are required in CFI mode. Query command of CFI mode is
placed first, then the Reset command exits CFI mode.
These are described in Table 2.
The Reset command exits from the CFI mode to the
Read mode, or Erase Suspend mode, Program Suspend
or read ID mode. The command is valid only when the
device is in the CFI mode.
Table 8-1. CFI mode: Identification Data Values
(All values in these tables are in hexadecimal)
Description
Address h
Data h
10
0051
11
0052
12
0059
13
0003
14
0000
15
0035
16
0000
17
0000
18
0000
19
0000
1A
0000
Address h
Data h
VCC supply, minimum (2.7V)
1B
0027
VCC supply, maximum (3.6V)
1C
0036
VPP supply, minimum (11.4V)
1D
00B4
VPP supply, maximum (12.6V)
1E
00C6
Typical timeout for single word write (2N us)
1F
0005
Typical timeout for maximum size buffer write (2N us)
20
0000
Typical timeout for individual sector erase (2N ms)
21
000A
Typical timeout for full chip erase (2N ms) (not supported)
22
0000
Maximum timeout for single word write times (2N X Typ)
23
0004
Maximum timeout for maximum size buffer write times (2N X Typ)
24
0000
Maximum timeout for individual sector erase times (2N X Typ)
25
0003
Maximum timeout for full chip erase times (not supported)
26
0000
Query-unique ASCII string "QRY"
Primary vendor command set and control interface ID code
Address for primary algorithm extended query table
Alternate vendor command set and control interface ID code (none)
Address for secondary algorithm extended query table (none)
Table 8-2. CFI Mode: System Interface Data Values
Description
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MX69F1602/1604C3T/B
Table 8-3. CFI Mode: Device Geometry Data Values
Description
Device size (2n bytes)
Flash device interface code (asynchronous x16)
Maximum number of bytes in write buffer=2n (not supported)
Number of erase sector regions within device (one or more continuous
same-size erase sectors at one sector region)
Address h
27
28
29
2A
2B
2C
Erase Sector Region 1 information
[2E,2D] = number of same-size sectors in region 1-1
[30, 2F] = region erase sector size in multiples of 256-bytes
2D
2E
2F
30
Erase Sector Region 2 information
[32,31] = number of same-size sectors in region 2-1
[34,33] = region erase sector size in multiples of 256-bytes
31
32
33
34
Data h
0015
0001
0000
0000
0000
0002
T B
1E 07
00 00
00 20
01 00
T B
07 1E
00 00
20 00
00 01
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MX69F1602/1604C3T/B
Table 8-4. CFI Mode: Primary Vendor-Specific Extended Query Data Values
Description
Query-unique ASCII string "PRI"
Major version number, ASCII
Minor version number, ASCII
Optional Feature & Command Support
bit 0 Chip Erase Supported (1=yes, 0=no)
bit 1 Suspend Erase Supported (1=yes, 0=no)
bit 2 Suspend Program Supported (1=yes, 0=no)
bit 3 Lock/Unlock Supported (1=yes, 0=no)
bit 4 Queued Erase Supported (1=yes, 0=no)
bit 5 Instant individual sector locking supported (1=yes, 0=no)
bit 6 Protection bits supported (1=yes, 0=no)
bit 7 Page mode read supported (1=yes, 0=no)
bit 8 Synchronous read support (1=yes, 0=no)
bits 9-31 revered for future use; undefined bits are "0"
Supported functions after suspend
bit 0 Program supported after erase suspend (1=yes, 0=no)
bit 1-7 Reserved for other supported options; undefined bits are "0"
Sector Lock Status
Define which bits in the sector status Register section of the Query are
implemented.
bit 0 sector Lock Status Register Lock/Unlock bit (bit 0) active; (1=yes, 0=no)
bit 1 sector Lock Status Register Lock-Down bit (bit 1) active; (1=yes, 0=no)
Bits 2-15 reserved for future use. Undefined bits are "0".
VCC Logic Supply Optimum Program/Erase Voltage (highest performance)
bits 7-4 BCD value in volts
bits 3-0 BCD value in 100mV
VPP Supply Optimum Program/Erase Voltage
bits 7-4 HEX value in volts
bits 3-0 BCD value in 100mV
Number of protection register in JEDEC ID space "00" indicates that
256 protection bytes are available
Protection Description
bit 0-7 = Lock/bytes JEDEC-plane physical low address
bit 8-15 = Lock/bytes JEDEC-plane physical high address
bit 16-23 = "n" such that 2n=factory pre-programmed bytes
bit 24-31 = "n" such that 2n=user programmed bytes
Address h
35
36
37
38
39
3A
3B
3C
3D
Data h
0050
0052
0049
0031
0030
66
00
00
00
3E
01
3F
40
03
00
41
33
42
C0
43
01
44
45
46
47
80
00
03
03
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MX69F1602/1604C3T/B
vide both high speed and low power features with a typical CMOS standby current of 1uA and maximum access time of 70ns in 3V operation.
2. SRAM--DESCRIPTION
The SRAM of mixed multi chip memory is a high performance, very low power CMOS Static Random Access
Memory.
Easy memory expansion is provided by an active HIGH
chip enable 2(CE2s) active LOW chip enable (CE1s)
and active LOW output enable (OEs) and three-state
output drivers.
The SRAM of MX69F1602/1604C3T/B is organized as
131,072 words by 16 bits / 262,144 words by 16 bits
and operates from a very low range of 2.7V to 3.6V supply voltage.
The SRAM of MX69F1602/1604C3T/B has an autmatic
power down feature, reducing the power consumption
significantly when chip is deselected.
Advanced CMOS technology and circuit techniques pro-
DC ELECTRICAL CHARACTERISTICS
Parameter Parameter
Name
VIL
Guaranteed Input Low
Voltage (2)
VIH
Guaranteed Input High
Voltage (2)
IIL
Input Leakage Current
IOL
Output Leakage Current
VI/O=0V to Vcc
VOL
VOH
ICC1
ICC2
ICC3
ICC4
Test Conditions
MIN.
-0.3
TYP.
(1)
-
2.2
Vccs=Max, VIN=0V to Vcc
Vccs=Max, CE1s=VIH or CE2s=VIL
or LB=UB=VIH or OEs=VIH,
VI/O=0V to Vcc
Output Low Voltage
Vccs=Max, IOL=2mA
Output High Voltage
Vccs=Min, IOH=-0.5mA
2.4
Active supply current
LBs and UBs<0.2V, CE1s<0.2V
f=10MHz (AC, MOS level)
CE2s>(Vccs)-0.2V other
inputs<0.2V or >(Vccs)-0.2V
f=1MHz
Output-open (duty 100%)
Active supply current
LBs and UBs=VIL, CE1s=VIL
f=10MHz (AC, TTL level)
CE2s=VIH other inputs=VIH or VIL
Output-open (duty 100%)
f=1MHz
Standby Power Suppply Vcc=max, CE1s=VIH or CE2s=VIL
Current (AC, CMOS)
IDQ=0mA
Standby supply current 1)CE2s=VIL, Other inputs=0 - Vccs
(AC, TTL)
2)CE1s=VIH, CE2s=VIH or VIL, Other
inputs=0 - Vccs
3) LBs and UBs=VIH, CE1s=VIH or VIL
CE2s=VIH or VIL, Other inputs=0 Vccs
MAX. Units
0.6
V
-
Vcc+0.3
V
-
±1
±1
uA
uA
50
0.4
70
V
V
mA
7
15
mA
50
70
mA
7
1
15
40
mA
uA
-
1.0
mA
1.Typical characteristics are at TA=25°C and Vcc=3.0V
2.These are absolute values with respect to device ground and all overshoots due to system or tester notice are
included.
3.Fmax=1/tRC.
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MX69F1602/1604C3T/B
POWER DOWN CHARACTERISTICS
(1) ELECTRICAL CHARACTERISTICS
Limits
Symbol
Parameter
Test Conditions
MIN.
TYP.
MAX. Units
S-Vcc(PD) Power down supply voltage
2.0
V
VI(S-BC)
Byte control input LBs, UBs
2.0
V
VI(CE1s)
Chip select input CE1s
2.0
V
VI(CE2s)
Chip select input CE2s
ICC(PD)
Power Down supply current
0.2
V
+70 ~ +85°C
-
-
30
uA
VCCs=3.0V
+40 ~ +70°C
-
-
15
uA
CE2s<0.2V
+25 ~ +40°C
-
1
3
uA
other inputs=0~3V
-40 ~ +25°C
-
0.3
1
uA
(2) TIMING REQUIREMENTS
Limits
Symbol
Parameter
Test Conditions
MIN.
TYP.
MAX. Units
tsu(PD)
Power down set up time
0
ns
trec(PD)
Power down recovery time
5
ms
(3) TIMING DIAGRAM
LBs, UBs control mode
S-Vcc
2.7V
2.7V
tsu(PD)
LBs
UBs
trec(PD)
2.2V
2.2V
LBs, UBs > (VCCs)-0.2V
CE1s control mode
VCCs
2.7V
2.7V
tsu(PD)
trec(PD)
2.2V
2.2V
CE1s
CE1s > (VCCs)-0.2V
CE2s control mode
VCCs
2.7V
2.7V
CE2s
0.2V
0.2V
tsu(PD)
trec(PD)
CE2s < 0.2V
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MX69F1602/1604C3T/B
AC TEST LOADS AND WAVEFORMS
AC TEST LOADS AND WAVEFORMS
Input Pulse Levels
Input Rise and Fall Times
Input and Output Timing
Reference Level
Supply Voltage
DQ
CL
Output loads:
Including scope and
jig capacitance
3.0/0V
5ns
1.5V
2.7V~3.6V
CL=30pF
CL=5pF (for ten. tdis)
FIGURE 1. Output load
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MX69F1602/1604C3T/B
AC ELECTRICAL CHARACTERISTICS
READ CYCLE
Limits
Symbol
Parameter
SRAM
70
MIN.
85
MAX.
70
MIN.
Units
MAX.
tCR
Read cycle time
85
ns
ta(A)
Address access time
70
85
ns
ta(CE1)
Chip select 1 access time
70
85
ns
ta(CE2)
Chip select 2 access time
70
85
ns
ta(LB)
Lower Byte control access time
70
85
ns
ta(UB)
Upper Byte control access time
70
85
ns
ta(OE)
Output enable access time
45
45
ns
tdis(CE1)
Output disable time after CE1s high
30
30
ns
tdis(CE2)
Output disable time after CE2s low
30
30
ns
tdis(LB)
Output disable time after LBs high
30
30
ns
tdis(UB)
Output disable time after UBs high
30
30
ns
tdis(OE)
Output disable time after OEs high
30
30
ns
ten(CE1)
Output enable time after CE1s low
10
10
ns
ten(CE2)
Output enable time after CE2s low
10
10
ns
ten(LB)
Output enable time after LBs low
10
10
ns
ten(UB)
Output enable time after UBs low
10
10
ns
ten(OE)
Output enable time after OEs low
5
5
ns
tv(A)
Data valid time after address
10
10
ns
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MX69F1602/1604C3T/B
READ CYCLE TIMING DIAGRAMS
tCR
A0~A16/A0~A17
ta(A)
LBs
tv(A)
ta(LB) or ta(UB)
UBs
(Note3)
(Note3)
tdis(LB) or tdis(UB)
ta(CE1)
CE1s
(Note3)
tdis(CE1)
(Note3)
ta(CE2)
CE2s
(Note3)
tdis(CE2)
(Note3)
ta(OE)
OEs
(Note3)
ten(OE)
tdis(OE)
(Note3)
WEs="H" level
Q0~15
ten(LB)
ten(UB)
ten(CE1)
ten(CE2)
VALID DATA
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MX69F1602/1604C3T/B
AC ELECTRICAL CHARACTERISTICS
WRITE CYCLE
Limits
Symbol
Parameter
SRAM
70
MIN.
85
MAX.
MIN.
Units
MAX.
tCW
Write cycle time
70
85
ns
tw(W)
Write pulse width
50
50
ns
tsu(A)
Address setup time
0
0
ns
tsu(A-WH)
Address setup time with respect to WEs
70
70
ns
tsu(LB)
Lower Byte control setup time
70
70
ns
tsu(UB)
Upper Byte control setup time
70
70
ns
tsu(CE1)
Chip select 1 setup time
70
70
ns
tsu(CE2)
Chip select 2 setup time
70
70
ns
tsu(D)
Data setup time
35
35
ns
th(D)
Data hold time
0
0
ns
trec(W)
Write recovery time
0
0
ns
tdis(W)
Output disable time WEs low
30
30
ns
tdis(OE)
Output disable time OEs high
30
30
ns
ten(W)
Output enable time WEs high
5
5
ns
ten(OE)
Output enable time from OEs low
5
5
ns
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MX69F1602/1604C3T/B
WRITE CYCLE (WEs control mode)
tCW
A0~A16/A0~A17
tsu(LB) or tsu(UB)
LBs
UBs
(Note3)
(Note3)
tsu(CE1)
CE1s
(Note3)
(Note3)
tsu(CE2)
CE2s
(Note3)
(Note3)
OEs
tsu(A-WH)
tw(W)
tsu(A)
trec(W)
tdis(W)
WEs
ten(OE)
tdis(OE)
ten(W)
DATA IN
STABLE
Q0~15
tsu(D)
th(D)
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MX69F1602/1604C3T/B
WRITE CYCLE (LBs, UBs control mode)
tCW
A0~A16/A0~A17
tsu(LB) or
tsu(A)
trec(W)
tsu(UB)
LBs
UBs
CE1s
(Note3)
(Note3)
(Note3)
(Note3)
CE2s
(Note5)
WEs
(Note4)
(Note3)
(Note3)
tsu(D)
th(D)
DATA IN
STABLE
Q0~15
Note 3: Hatching indicates the state is "don't care".
Note 4: A Write occurs during CE1s low, CE2s high overlaps LBs and/or UBs low and WEs low.
Note 5: When the falling edge of WEs is simultaneously or prior to the falling edge of LBs and/or UBs or the falling
edge of CE1s or rising edge of CE2s the outputs are maintained in the high impedance state.
Note 6: Don't apply inverted phase signal externally when I/O pin is in output mode.
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MX69F1602/1604C3T/B
WRITE CYCLE (CE1s control mode)
tCW
A0~A16/A0~A17
LBs
UBs
(Note3)
tsu(A)
tsu(CE1)
trec(W)
(Note3)
CE1s
CE2s
(Note3)
(Note3)
(Note5)
WEs
(Note4)
(Note3)
(Note3)
tsu(D)
th(D)
DATA IN
STABLE
Q0~15
WRITE CYCLE (CE2s control mode)
tCW
A0~A16/A0~A17
LBs
UBs
(Note3)
tsu(A)
tsu(CE1)
trec(W)
(Note3)
CE1s
(Note3)
CE2s
(Note3)
(Note5)
WEs
(Note4)
(Note3)
(Note3)
tsu(D)
th(D)
DATA IN
STABLE
Q0~15
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MX69F1602/1604C3T/B
ORDERING INFORMATION
PLASTIC PACKAGE
PART NO.
Access Time
Temperature
(ns)
Range
Type
Package Type
MX69F1602C3TXBI-70
70
-40~85°C
66 Ball FBGA
FBGA
0.8mm
MX69F1602C3BXBI-70
70
-40~85°C
66 Ball FBGA
FBGA
0.8mm
MX69F1602C3TXBI-90
90
-40~85°C
66 Ball FBGA
FBGA
0.8mm
MX69F1602C3BXBI-90
90
-40~85°C
66 Ball FBGA
FBGA
0.8mm
MX69F1604C3TXBI-70
70
-40~85°C
66 Ball FBGA
FBGA
0.8mm
MX69F1604C3BXBI-70
70
-40~85°C
66 Ball FBGA
FBGA
0.8mm
MX69F1604C3TXBI-90
90
-40~85°C
66 Ball FBGA
FBGA
0.8mm
MX69F1604C3BXBI-90
90
-40~85°C
66 Ball FBGA
FBGA
0.8mm
Ball Pitch
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MX69F1602/1604C3T/B
PACKAGE INFORMATION
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MX69F1602/1604C3T/B
REVISION HISTORY
Revision No. Description
0.1
1. Add Package Information
0.2
1. Changed Part No. from MX28F1602/1604C3T/B to
MX69F1602/1604C3T/B
0.3
1. Modified Pin Assignment
0.4
1. Changed package size from 10x8x1.4mm to 11x8x1.4mm
0.5
1. Modified absolute maximum ratings
Page
P49
All
Date
NOV/06/2002
NOV/20/2002
P4
P2,4
P7
NOV/22/2002
MAR/06/2003
JUL/09/2003
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MX69F1602/1604C3T/B
MACRONIX INTERNATIONAL CO., LTD.
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