FM22LD16_09 RAMTRON [Ramtron International Corporation], FM22LD16_09 Datasheet - Page 5

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FM22LD16_09

Manufacturer Part Number
FM22LD16_09
Description
4Mbit F-RAM Memory
Manufacturer
RAMTRON [Ramtron International Corporation]
Datasheet
along with a new column address provides a page
mode write access.
Precharge Operation
The precharge operation is an internal condition in
which the state of the memory is being prepared for a
new access. Precharge is user-initiated by driving the
/CE signal high. It must remain high for at least the
minimum precharge time t
Precharge is also activated by changing the upper
addess A(17:2). The current row is first closed prior
to accessing the new row. The device automatically
detects an upper order address change which starts a
precharge operation, the new address is latched, and
the new read data is valid within the t
access time. Refer to the Read Cycle Timing 1
diagram on page 10. Likewise a similar sequence
occurs for write cycles. Refer to the Write Cycle
Timing 3 diagram on page 12. The rate at which
random addresses can be issued is t
respectively.
Software Write Protection
The 256Kx16 address space is divided into 8 sectors
(blocks) of 32Kx16 each. Each sector can be
individually software write-protected and the settings
are nonvolatile. A unique address and command
sequence invokes the write protection mode.
To modify write protection, the system host must
issue six read commands, three write commands, and
a final read command. The specific sequence of read
addresses must be provided in order to access to the
write protect mode. Following the read address
sequence, the host must write a data byte that
specifies the desired protection state of each sector.
For confirmation, the system must then write the
complement of the protection byte immediately
following the protection byte. Any error that occurs
including read addresses in the wrong order, issuing a
seventh read address, or failing to complement the
protection value will leave the write protection
unchanged.
The write protect state machine monitors all
addresses, taking no action until this particular
read/write sequence occurs. During the address
sequence, each read will occur as a valid operation
and data from the corresponding addresses will be
driven onto the data bus. Any address that occurs out
of sequence will cause the software protection state
machine to start over. After the address sequence is
completed, the next operation must be a write cycle.
Rev. 2.0
Dec. 2009
PC
.
RC
AA
and t
address
WC
,
The data byte contains the write-protect settings. This
value will not be written to the memory array, so the
address is a don’t-care. Rather it will be held pending
the next cycle, which must be a write of the data
complement to the protection settings. If the
complement is correct, the write protect settings will
be adjusted. If not, the process is aborted and the
address sequence starts over. The data value written
after the correct six addresses will not be entered into
memory.
The protection data byte consists of 8-bits, each
associated with the write protect state of a sector. The
data byte must be driven to the lower 8-bits of the
data bus, DQ(7:0). Setting a bit to 1 write protects the
corresponding sector; a 0 enables writes for that
sector. The following table shows the write-protect
sectors with the corresponding bit that controls the
write-protect setting.
Write Protect Sectors – 32K x16 blocks
The write-protect read address sequence follows:
* If /CE is low entering the sequence, then an
address of 00000h must precede 24555h.
The address sequence provides a very secure way of
modifying the protection. The write-protect sequence
has a 1 in 3 x 10
exactly the 1
reduced by requiring three more write cycles, one that
requires an exact inversion of the data byte. A flow
chart of the entire write protect operation is shown in
Figure 2. The write-protect settings are nonvolatile.
The factory default: all blocks are unprotected.
Sector 7
Sector 6
Sector 5
Sector 4
Sector 3
Sector 2
Sector 1
Sector 0
1.
2.
3.
4.
5.
6.
7.
8.
9.
10. 00000h
24555h *
3AAAAh
02333h
1CCCCh
000FFh
3EF00h
3AAAAh
1CCCCh
0FF00h
st
six addresses. The odds are further
3FFFFh – 38000h
37FFFh – 30000h
2FFFFh – 28000h
27FFFh – 20000h
1FFFFh – 18000h
17FFFh – 10000h
0FFFFh – 08000h
07FFFh – 00000h
32
FM22LD16 - 256Kx16 FRAM
chance of randomly accessing
Page 5 of 14

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