X9530 Datasheet, PDF(18/30 Page) Xicor Inc. – Temperature Compensated Laser Diode Controller

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X9530 Datasheet, PDF (18/30 Pages) Xicor Inc. – Temperature Compensated Laser Diode Controller

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X9530

Figure 17. Example: Writing 12 bytes to a 16-byte page starting at location 11.

7 bytes

Address=0

Address=6

5 b5ybtyetess

Address=11

Address=7

Address Pointer

Ends Up Here

Address=15

The four registers Control 1 through 4, have a

nonvolatile and a volatile cell for each bit. At power-up,

the content of the nonvolatile cells is automatically

recalled and written to the volatile cells. The content of

the volatile cells controls the X9530âs functionality. If

bit NV1234 in the Control 0 register is set to â1â, a

Write operation to these registers writes to both the

volatile and nonvolatile cells. If bit NV1234 in the

Control 0 register is set to â0â, a Write operation to

these registers only writes to the volatile cells. In both

cases the newly written values effectively control the

X9530, but in the second case, those values are lost

when the part is powered down.

If bit NV1234 is set to â0â, a Byte Write operation to

Control registers 0 or 5 causes the value in the

nonvolatile cells of Control registers 1 through 4 to be

recalled into their corresponding volatile cells, as

during power-up. This doesnât happen when the WP

pin is LOW, because Write Protection is enabled. It is

generally recommended to configure Control registers

0 and 5 before writing to Control registers 1 through 4.

When reading any of the control registers 1, 2, 3, or 4,

the Data Bytes are always the content of the

corresponding nonvolatile cells, even if bit NV1234 is

"0" (See âControl and Status Register Formatâ).

Read Operation

A Read operation consist of a three byte instruction

followed by one or more Data Bytes (See Figure 19).

The master initiates the operation issuing the following

sequence: a START, the Slave Address byte with the

R/W bit set to â0â, an Address Byte, a second START,

and a second Slave Address byte with the R/W bit set

to â1â. After each of the three bytes, the X9530

responds with an ACK. Then the X9530 transmits

Data Bytes as long as the master responds with an

ACK during the SCL cycle following the eigth bit of

each byte. The master terminates the read operation

(issuing a STOP condition) following the last bit of the

last Data Byte (See Figure 19).

Figure 18. Writing to Control Registers 1, 2, 3, and 4

Signals from

the Master

Signal at SDA

Signals from

the Slave

Write

Slave

Address

Byte = 81h

Four Data Bytes

Data Byte for

Control 1

Data Byte for

Control 4

10 10

0 10 00 0 0 01

FN8211.0

March 10, 2005

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