TE28F160S375 Intel, TE28F160S375 Datasheet - Page 27

TE28F160S375

Manufacturer Part Number

TE28F160S375

Description

Manufacturer

Intel

Datasheet

1.TE28F160S375.pdf (52 pages)

Specifications of TE28F160S375

Cell Type

NOR

Density

16Mb

Access Time (max)

75ns

Interface Type

Parallel

Boot Type

Not Required

Address Bus

21/20Bit

Operating Supply Voltage (typ)

3/3.3V

Operating Temp Range

-40C to 85C

Package Type

TSOP

Program/erase Volt (typ)

2.7/3.3/5V

Sync/async

Asynchronous

Operating Temperature Classification

Industrial

Operating Supply Voltage (min)

2.7V

Operating Supply Voltage (max)

3.6V

Word Size

8/16Bit

Number Of Words

2M/1M

Supply Current

30mA

Mounting

Surface Mount

Pin Count

Lead Free Status / Rohs Status

Not Compliant

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This two-step command sequence of setup followed

by execution ensures that block contents are not

accidentally erased. An invalid Full Chip Erase

command sequence will result in both Status

reliable full chip erasure can only occur when

these voltages, block contents are protected

against erasure. If full chip erase is attempted while

WP# = V

chip erase cannot be suspended.

4.8

To program the flash device via the write buffers, a

Write to Buffer command sequence is initiated. A

variable number of bytes or words, up to the buffer

size, can be written into the buffer and programmed

to the flash device. First, the Write to Buffer setup

command is issued along with the Block Address.

At this point, the eXtended Status Register

information is loaded and XSR.7 reverts to the

“buffer available” status. If XSR.7 = 0, no write

buffer is available. To retry, continue monitoring

XSR.7 by issuing the Write to Buffer setup

command with the Block Address until XSR.7 = 1.

When XSR.7 transitions to a “1,” the buffer is ready

for loading.

Now a Word/Byte count is issued at an address

within the block. On the next write, a device start

address is given along with the write buffer data.

For maximum programming performance and lower

power, align the start address at the beginning of a

Write Buffer boundary. Subsequent writes must

supply additional device addresses and data,

depending on the count. All subsequent addresses

must lie within the start address plus the count.

After the final buffer data is given, a Write Confirm

command is issued. This initiates the WSM to begin

copying the buffer data to the flash memory. If a

command other than Write Confirm is written to the

device, an “Invalid Command/Sequence” error will

be generated and Status Register bits SR.5 and

SR.4 will be set to “1.” For additional buffer writes,

issue another Write to Buffer setup command and

check XSR.7. The write buffers can be loaded while

the WSM is busy as long as XSR.7 indicates that a

buffer is available. Refer to Figure 7 for the Write to

Buffer flowchart.

ADVANCE INFORMATION

= V

PPLK

CC1/2

Write to Buffer Command

, only unlocked blocks are erased. Full

, SR.3 and SR.5 will be set to 1. When

and V

= V

PPH1/2

. In the absence of

If an error occurs while writing, the device will stop

programming, and Status Register bit SR.4 will be

set to a “1” to indicate a program failure. Any time a

media failure occurs during a program or an erase

(SR.4 or SR.5 is set), the device will not accept any

more Write to Buffer commands. Additionally, if the

user attempts to write past an erase block boundary

with a Write to Buffer command, the device will

abort programming. This will generate an “Invalid

Command/Sequence” error and Status Register bits

SR.5 and SR.4 will be set to “1.” To clear SR.4

and/or SR.5, issue a Clear Status Register

command.

Reliable buffered programming can only occur

when V

programming is attempted while V

Status Register bits SR.4 and SR.5 will be set to

“1.” Programming attempts with invalid V

voltages produce spurious results and should not

be attempted. Finally, successful programming

requires that the corresponding Block Lock-Bit be

cleared, or WP# = V

attempted when the corresponding Block Lock-Bit

is set and WP# = V

“1.”

4.9

Byte/Word programming is executed by a two-cycle

command sequence. Byte/Word Program setup

(standard 40H or alternate 10H) is written, followed

by a second write that specifies the address and

data (latched on the rising edge of WE#). The WSM

then takes over, controlling the program and verify

algorithms internally. After the write sequence is

written, the device automatically outputs Status

completion of the program event by analyzing STS

in level RY/BY# mode or Status Register bit SR.7.

When programming is complete, Status Register bit

SR.4 should be checked. If a programming error is

detected, the Status Register should be cleared.

The internal WSM verify only detects errors for “1”s

that do not successfully program to “0”s. The CUI

remains in read Status Register mode until it

receives another command. Refer to Figure 8 for

the Word/Byte Program flowchart.

Also, Reliable byte/word programming can only

occur when V

absence of this high voltage, contents are protected

against programming. If a byte/word program is

Byte/Word Program Commands

= V

CC1/2

, SR.1 and SR.4 will be set to

and V

. If a buffered write is

and V

28F160S3, 28F320S3

= V

PPH1/2

and V

. In the

PPLK

. If

TE28F160S375 Intel, TE28F160S375 Datasheet - Page 27

TE28F160S375

Specifications of TE28F160S375

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