MAXIM DS1873

19-4986; Rev 0; 9/09
KIT
ATION
EVALU
E
L
B
A
AVAIL
SFP+ Controller with Analog LDD Interface
The DS1873 controls and monitors all functions for SFF,
SFP, and SFP+ modules including all SFF-8472 functionality. The DS1873 provides APC loop, modulation
current control, and eye safety functionality. The
DS1873 continuously monitors for high output current,
high bias current, and low and high transmit power to
ensure that laser shutdown for eye safety requirements
are met without adding external components.
Six ADC channels monitor VCC, temperature, and four
external monitor inputs (MON1–MON4) that can be
used to meet all monitoring requirements. MON3 is differential with support for common mode to VCC. Two
digital-to-analog (DAC) outputs with temperatureindexed lookup tables (LUTs) are available for additional monitoring and control functionality.
Applications
SFF, SFP, and SFP+ Transceiver Modules
BIAS
MOD
GND
MON2
VCC
N.C.
TOP VIEW
GND
Pin Configuration
21
20
19
18
17
16
15
14
MON1
N.C. 23
13
MON3N
DAC1 24
12
MON3P
11
MON4
10
TXDOUT
9
RSEL
8
GND
DS1873
VCC 26
*EP
4
5
LOS
3
TXF
SCL
2
RSELOUT
1
SDA
OUT1 28
6
7
THIN QFN
(5mm × 5mm × 0.8mm)
*EXPOSED PAD.
♦ Six Analog Monitor Channels: Temperature, VCC,
MON1–MON4
MON1–MON4 Support Internal and External
Calibration
Scalable Dynamic Range
Internal Direct-to-Digital Temperature Sensor
Alarm and Warning Flags for All Monitored
Channels
♦ Four 10-Bit Delta-Sigma Outputs with 36 Entry
Temperature LUTs
Laser Bias Controlled by APC Loop and
Temperature LUT to Compensate for Tracking
Error
Laser Modulation Controlled by 72-Entry
Temperature LUT
Two Additional DACs Controlled by One
72-Entry and One 36-Entry Temperature LUT
♦ Digital I/O Pins: Five Inputs, Five Outputs
♦ 120 Bytes of Password-1 Protected Memory
♦ 128 Bytes of Password-2 Protected Memory in
Main Device Address
♦ 256 Additional Bytes Located at A0h Slave
Address
♦ I2C-Compatible Interface
♦ +2.85V to +3.9V Operating Voltage Range
♦ -40°C to +95°C Operating Temperature Range
♦ 28-Pin TQFN (5mm x 5mm) Package
Ordering Information
TXD
+
IN1
LOSOUT 27
♦ Meets All SFF-8472 Control and Monitoring
Requirements
♦ Comprehensive Fault-Measurement System with
Maskable Laser Shutdown Capability
♦ Flexible, Two-Level Password Scheme Provides
Three Levels of Security
REFIN 22
DAC2 25
Features
PART
TEMP RANGE
PIN-PACKAGE
DS1873T+
-40°C to +95°C
28 TQFN-EP*
DS1873T+T&R
-40°C to +95°C
28 TQFN-EP*
+Denotes a lead(Pb)-free/RoHS-compliant package.
T&R = Tape and reel.
*EP = Exposed pad.
________________________________________________________________ Maxim Integrated Products
For pricing, delivery, and ordering information, please contact Maxim Direct at 1-888-629-4642,
or visit Maxim’s website at www.maxim-ic.com.
1
DS1873
General Description
DS1873
SFP+ Controller with Analog LDD Interface
TABLE OF CONTENTS
Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5
Recommended Operating Conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5
DC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .5
MOD, BIAS, DAC1, DAC2 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
Analog Quick Trip Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
Analog Voltage Monitoring Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .6
Digital Thermometer Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
AC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
Timing Characteristics (Control Loop and Quick Trip) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .7
I2C AC Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8
Nonvolatile Memory Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .8
Typical Operating Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .9
Pin Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .10
Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .11
Typical Operating Circuit . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12
Detailed Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12
BIAS DAC/APC Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12
BIAS and MOD Output Control During Power-Up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13
BIAS and MOD DACs as a Function of Transmit Disable (TXD) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14
APC and Quick-Trip Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14
Monitors and Fault Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15
Monitors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15
Five Quick-Trip Monitors and Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15
Six ADC Monitors and Alarms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15
ADC Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15
Right-Shifting ADC Result . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15
Differential MON3 Input . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16
Enhanced RSSI Monitoring (Dual-Range Functionality) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16
Low-Voltage Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19
Power-On Analog (POA)
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19
Delta-Sigma Outputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19
Digital I/O Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21
LOS, LOSOUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21
IN1, RSEL, OUT1, RSELOUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21
TXF, TXD, TXDOUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22
Transmit Fault (TXF) Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23
Die Identification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23
2
_______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
I2C Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23
I2C Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .25
Memory Organization . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .26
Shadowed EEPROM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27
Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .28
Lower Memory Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .28
Table 01h Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .29
Table 02h Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .30
Table 04h Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .31
Table 05h Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .31
Table 06h Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32
Table 07h Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .32
Table 08h Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .33
Auxiliary A0h Memory Register Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .33
Lower Memory Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .34
Table 01h Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .47
Table 02h Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .54
Table 04h Register Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .79
Table 06h Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .80
Table 07h Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .81
Table 08h Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .83
Auxiliary Memory A0h Register Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .84
Applications Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .85
Power-Supply Decoupling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .85
SDA and SCL Pullup Resistors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .85
Package Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .85
_______________________________________________________________________________________
3
DS1873
TABLE OF CONTENTS (continued)
I2C Communication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23
DS1873
SFP+ Controller with Analog LDD Interface
LIST OF FIGURES
Figure 1. Power-Up Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13
Figure 2. TXD Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14
Figure 3. APC Loop and Quick-Trip Sample Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .14
Figure 4. ADC Round-Robin Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16
Figure 5. MON3 Differential Input for High-Side RSSI . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .16
Figure 6. RSSI Flowchart . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17
Figure 7. RSSI with Crossover Enabled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18
Figure 8. RSSI with Crossover Disabled . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .18
Figure 9. Low-Voltage Hysteresis Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .19
Figure 10. Recommended RC Filter for DAC1/DAC2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .20
Figure 11. 3-Bit Delta-Sigma Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .20
Figure 12. MOD, DAC1, and DAC2 Offset LUTs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .21
Figure 13. Logic Diagram 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22
Figure 14. Logic Diagram 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .22
Figure 15a. TXF Nonlatched Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23
Figure 15b. TXF Latched Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23
Figure 16. I2C Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24
Figure 17. Example I2C Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .25
Figure 18. Memory Map . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .27
LIST OF TABLES
Table 1. Acronyms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13
Table 2. ADC Default Monitor Full-Scale Ranges . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .15
Table 3. MON3 Hysteresis Threshold Values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17
Table 4. MON3 Configuration Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .17
4
_______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
Operating Temperature Range ...........................-40°C to +95°C
Programming Temperature Range .........................0°C to +95°C
Storage Temperature Range .............................-55°C to +125°C
Soldering Temperature...........................Refer to the IPC/JEDEC
J-STD-020 Specification.
*Subject to not exceeding +4.2V.
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
RECOMMENDED OPERATING CONDITIONS
(TA = -40°C to +95°C, unless otherwise noted.)
PARAMETER
SYMBOL
MAX
UNITS
+2.85
+3.9
V
VIH:1
0.7 x
VCC
VCC +
0.3
V
Low-Level Input Voltage
(SDA, SCL)
VIL:1
-0.3
0.3 x
VCC
V
High-Level Input Voltage
(TXD, TXF, RSEL, IN1, LOS)
VIH:2
2.0
VCC +
0.3
V
Low-Level Input Voltage
(TXD, TXF, RSEL, IN1, LOS)
VIL:2
-0.3
+0.8
V
TYP
MAX
UNITS
2.5
10
mA
1
μA
Main Supply Voltage
VCC
High-Level Input Voltage
(SDA, SCL)
CONDITIONS
(Note 1)
MIN
TYP
DC ELECTRICAL CHARACTERISTICS
(VCC = +2.85V to +3.9V, TA = -40°C to +95°C, unless otherwise noted.)
PARAMETER
SYMBOL
Supply Current
ICC
Output Leakage
(SDA, OUT1, RSELOUT,
LOSOUT, TXF)
ILO
Low-Level Output Voltage
(SDA, MOD, BIAS, OUT1,
RSELOUT, LOSOUT, TXDOUT,
DAC1, DAC2, TXF)
VOL
High-Level Output Voltage
(MOD, BIAS, DAC1, DAC2,
TXDOUT)
VOH
CONDITIONS
MIN
(Notes 1, 2)
I OL = 4mA
0.4
I OL = 6mA
0.6
V
I OH = 4mA
VCC 0.4
V
TXDOUT Before EEPROM Recall
See Figure 14
10
100
nA
MOD, BIAS, DAC1, and DAC2
Before LUT Recall
See Figure 12
10
100
nA
1
μA
Input Leakage Current
(SCL, TXD, LOS, RSEL, IN1)
ILI
Digital Power-On Reset
POD
1.0
2.2
V
Analog Power-On Reset
POA
2.0
2.75
V
_______________________________________________________________________________________
5
DS1873
ABSOLUTE MAXIMUM RATINGS
Voltage Range on MON1–MON4, RSEL,
IN1, LOS, TXF, and TXD Pins
Relative to Ground .................................-0.5V to (VCC + 0.5V)*
Voltage Range on VCC, SDA, SCL, OUT1,
RSELOUT, and LOSOUT Pins
Relative to Ground..............................................-0.5V to +4.2V
DS1873
SFP+ Controller with Analog LDD Interface
MOD, BIAS, DAC1, DAC2 ELECTRICAL CHARACTERISTICS
(VCC = +2.85V to +3.9V, TA = -40°C to +95°C, unless otherwise noted.)
PARAMETER
Main Oscillator Frequency
Delta-Sigma Input-Clock
Frequency
Reference Voltage Input (REFIN)
SYMBOL
CONDITIONS
MIN
TYP
UNITS
f OSC
5
MHz
fDS
f OSC/2
MHz
VREFIN
Minimum 0.1μF to GND
Output Range
2
VCC
V
0
VREFIN
V
10
Bits
35
100
TYP
MAX
UNITS
Output Resolution
Output Impedance
MAX
RDS
ANALOG QUICK TRIP CHARACTERISTICS
(VCC = +2.85V to +3.9V, TA = -40°C to +95°C, unless otherwise noted.)
PARAMETER
MON2, TXP HI, TXP LO FullScale Voltage
SYMBOL
CONDITIONS
MIN
VAPC
HBIAS LOS Full-Scale Voltage
MON2 Input Resistance
35
Resolution
Error
TA = +25°C
2.5
V
1.25
V
50
65
k
8
Bits
±2
%FS
Integral Nonlinearity
-1
+1
LSB
Differential Nonlinearity
-1
+1
LSB
+2.5
%FS
Temperature Drift
-2.5
LOS Offset
-5
mV
ANALOG VOLTAGE MONITORING CHARACTERISTICS
(VCC = +2.85V to +3.9V, TA = -40°C to +95°C, unless otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
ADC Resolution
ACC
Update Rate for Temperature,
MON1–MON4, and VCC
tRR
Input/Supply Offset
(MON1–MON4, VCC)
VOS
At factory setting
MAX
VCC
MON3 Fine
UNITS
Bits
0.25
0.50
%FS
64
75
ms
(Note 3)
0
5
LSB
(Note 4)
6.5536
MON1–MON4
6
TYP
13
Input/Supply Accuracy
(MON1–MON4, VCC)
Factory Setting
MIN
2.5
312.5
_______________________________________________________________________________________
V
μV
SFP+ Controller with Analog LDD Interface
DS1873
DIGITAL THERMOMETER CHARACTERISTICS
(VCC = +2.85V to +3.9V, TA = -40°C to +95°C, unless otherwise noted.)
PARAMETER
Thermometer Error
SYMBOL
T ERR
CONDITIONS
-40°C to +95°C
MIN
TYP
-3
MAX
UNITS
+3
°C
MAX
UNITS
AC ELECTRICAL CHARACTERISTICS
(VCC = +2.85V to +3.9V, TA = -40°C to +95°C, unless otherwise noted.)
PARAMETER
SYMBOL
CONDITIONS
MIN
TYP
TXD Enable
t OFF
From TXD to BIAS DAC and MOD DAC
disable
5
μs
Recovery from TXD Disable
(Figure 14)
t ON
From TXD to BIAS DAC and MOD DAC
enable
5
μs
Recovery After Power-Up
Fault Reset Time (to TXF = 0)
Fault Assert Time (to TXF = 1)
From VCC > VCC LO alarm (Note 5)
20
t INITR1
From TXD
131
t INITR2
From VCC > VCC LO alarm (Note 5)
161
tFAULT
After HTXP, LTXP, HBATH, IBIASMAX
(Note 6)
15
μs
tINIT_DAC
ms
ms
LOSOUT Assert Time
tLOSS_ON
LLOS (Notes 6, 7)
15
μs
LOSOUT Deassert Time
tLOSS_OFF
HLOS (Notes 6, 8)
15
μs
MAX
UNITS
TIMING CHARACTERISTICS (CONTROL LOOP AND QUICK TRIP)
(VCC = +2.85V to +3.9V, TA = -40°C to +95°C, unless otherwise noted.)
PARAMETER
SYMBOL
Output-Enable Time Following POA
t INIT
(Note 5)
tSEARCH
(Note 9)
Binary Search Time
CONDITIONS
MIN
TYP
20
8
ms
10
BIAS
Samples
_______________________________________________________________________________________
7
DS1873
SFP+ Controller with Analog LDD Interface
I2C AC ELECTRICAL CHARACTERISTICS
(VCC = +2.85V to +3.9V, TA = -40°C to +95°C, timing referenced to VIL(MAX) and VIH(MIN), unless otherwise noted.) (See Figure 16.)
PARAMETER
SYMBOL
SCL Clock Frequency
Clock Pulse-Width Low
Clock Pulse-Width High
Bus-Free Time Between STOP and START
Condition
START Hold Time
START Setup Time
Data Out Hold Time
Data In Setup Time
Rise Time of Both SDA and SCL Signals
Fall Time of Both SDA and SCL Signals
STOP Setup Time
EEPROM Write Time
Capacitive Load for Each Bus Line
f SCL
tLOW
tHIGH
CONDITIONS
(Note 10)
tBUF
tHD:STA
t SU:STA
tHD:DAT
t SU:DAT
tR
tF
t SU:STO
tW
CB
MIN
TYP
0
1.3
0.6
MAX
UNITS
400
kHz
μs
μs
1.3
(Note 11)
(Note 11)
μs
0.6
0.6
0
100
20 + 0.1CB
20 + 0.1CB
0.6
20
400
μs
μs
μs
ns
ns
ns
μs
ms
pF
MAX
UNITS
0.9
300
300
(Note 12)
NONVOLATILE MEMORY CHARACTERISTICS
(VCC = +2.85V to +3.9V, unless otherwise noted.)
PARAMETER
EEPROM Write Cycles
SYMBOL
CONDITIONS
MIN
At +25°C
200,000
At +85°C
50,000
TYP
All voltages are referenced to ground. Current into the IC is positive, and current out of the IC is negative.
Inputs are at supply rail. Outputs are not loaded.
This parameter is guaranteed by design.
Full-scale is user programmable.
A temperature conversion is completed and the MOD DAC value is recalled from the LUT and VCC has been measured to
be above VCC LO alarm.
Note 6: The sampling time is 1.6µs per cycle. Each input is sampled every 8 cycles.
Note 7: This specification is the time it takes from MON3 voltage falling below the LLOS trip threshold to LOSOUT asserted high.
Note 8: This specification is the time it takes from MON3 voltage rising above the HLOS trip threshold to LOSOUT asserted low.
Note 9: Assuming an appropriate initial step is programmed that would cause the power to exceed the APC set point within four
steps, the bias output will be within 3% within the time specified by the binary search time. See the BIAS and MOD Output
Control During Power-Up section.
Note 10: I2C interface timing shown is for fast mode (400kHz). This device is also backward compatible with I2C standard mode
timing.
Note 11: CB—the total capacitance of one bus line in pF.
Note 12: EEPROM write begins after a STOP condition occurs.
Note 1:
Note 2:
Note 3:
Note 4:
Note 5:
8
_______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
SUPPLY CURRENT vs. SUPPLY VOLTAGE
2.4
+25°C
2.6
VCC = 2.8V
VCC = 3.9V
2.5
2.4
VCC = 3.3V
2.3
-40°C
2.1
2.1
3.45
3.75
-15
-40
10
35
60
0
85
-1
0.6
0.4
0.2
0
-0.2
-0.4
-3
800
0.6
0.4
0.2
0
-0.2
-0.4
-0.8
-0.8
-1.0
-1.0
1000
0.5
0
DAC1 AND DAC2 POSITION (DEC)
1.0
1.5
2.0
2.5
0
DAC SETTLING TIME
(40% TO 60%)
1.0
1.5
2.0
2.5
DAC SETTLING TIME
(60% TO 40%)
67.7% OF PEAK
DS1873 toc08
DAC OUTPUT
DS1873 toc07
DAC OUTPUT
0.5
MON1 TO MON4 INPUT VOLTAGE (V)
MON1 TO MON4 INPUT VOLTAGE (V)
1.0193ms
1000
-0.6
-0.6
-2
800
USING FACTORY PROGRAMMED
FULL-SCALE VALUE OF 2.5V
0.8
MON1 TO MON4 DNL (LSB)
MON1 TO MON4 INL (LSB)
0
600
1.0
DS1873 toc05
DS1873 toc04
USING FACTORY PROGRAMMED
FULL-SCALE VALUE OF 2.5V
0.8
400
MON1 TO MON4 DNL
1.0
1
600
200
DAC1 AND DAC2 POSITION (DEC)
MON1 TO MON4 INL
2
DAC1 AND DAC2 INL (LSB)
-0.4
-0.8
DAC1 AND DAC2 INL
400
0
-0.2
TEMPERATURE (°C)
3
200
0.2
-1.0
VCC (V)
0
0.4
DS1873 toc06
2.2
3.15
0.6
-0.6
2.2
2.85
DS1873 toc03
0.8
DAC1 AND DAC2 DNL (LSB)
SUPPLY CURRENT (mA)
SUPPLY CURRENT (mA)
2.5
2.3
SDA = SCL = VCC
2.7
+95°C
2.6
1.0
DS1873 toc02
SDA = SCL = VCC
2.7
DAC1 AND DAC2 DNL
SUPPLY CURRENT vs. TEMPERATURE
2.8
DS1873 toc01
2.8
33.3% OF LOW
990.4μs
TIME (μs)
TIME (μs)
_______________________________________________________________________________________
9
DS1873
Typical Operating Characteristics
(VCC = +2.85V to +3.9V, TA = +25°C, unless otherwise noted.)
DS1873
SFP+ Controller with Analog LDD Interface
Typical Operating Characteristics (continued)
(VCC = +2.85V to +3.9V, TA = +25°C, unless otherwise noted.)
DAC OUTPUT RIPPLE AT 3FFFh
DAC OUTPUT RIPPLE AT 0001h
DS1873 toc10
DS1873 toc09
DAC POSITION = 0001h
DAC POSITION = 3FFFh
FILTER
OUTPUT
FILTER
OUTPUT
0.1mV
0.68mV
3V/div
DAC2
OUTPUT
3V/div
DAC2
OUTPUT
TIME (100μs/div)
TIME (100μs/div)
Pin Description
PIN
NAME
FUNCTION
1
RSELOUT
2
SCL
I2C Serial-Clock Input
3
SDA
I2C Serial-Data Input/Output
Open-Drain Rate-Select Output
4
TXF
Transmit-Fault Input and Output. The output is open drain.
5
LOS
Loss-of-Signal Input
6
IN1
Digital Input. General-purpose input with AS1 in SFF-8079 or RS1 in SFF-8431.
7
TXD
Transmit-Disable Input
8, 18, 21
GND
Ground Connection
9
RSEL
Rate-Select Input
10
TXDOUT
Transmit-Disable Output
11
MON4
External Monitor Input 4
12, 13
MON3P, MON3N
10
Differential External Monitor Input 3 and LOS LO Quick Trip
14
MON1
15, 23
N.C.
No Connection
16, 26
VCC
Power-Supply Input
17
MON2
External Monitor Input 2. Feedback voltage for APC loop and HTXP/LTXP quick trip.
19
MOD
MOD DAC, Delta-Sigma Output
20
BIAS
BIAS DAC, Delta-Sigma Output
22
REFIN
24, 25
DAC1, DAC2
27
LOSOUT
28
OUT1
—
EP
External Monitor Input 1 and HBATH Quick Trip
Reference Input for DAC1 and DAC2
Delta-Sigma Output 1/2
Open-Drain Receive Loss-of-Signal Output
Open-Drain Digital Output. General-purpose output with AS1 output in SFF-8079 or RS1 output
in SFF-8431.
Exposed Pad (Connect to GND)
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
REFIN
VCC
VCC
SDA
I2C
SCL
INTERFACE
MAIN MEMORY
EEPROM/SRAM
ADC CONFIGURATION/RESULTS,
SYSTEM STATUS/CONTROL BITS,
ALARMS/WARNINGS,
LOOKUP TABLES,
USER MEMORY
EEPROM
256 BYTES
AT A0h
VCC
MON3P
MON3N
DAC2
10 BITS
DAC2
MOD DAC
10 BITS
MOD
BIAS
APC
INTEGRATOR
ANALOG MUX
MON2
DAC1
BIAS DAC
10 BITS
13-BIT
ADC
MON1
DAC1
10 BITS
8-BIT
QTs
MON4
TEMPERATURE
SENSOR
TXF
POWER-ON
ANALOG
INTERRUPT
VCC
LOGIC
CONTROL
TXD
TXDOUT
RSELOUT
RSEL
OUT1
IN1
LOGIC
CONTROL
LOSOUT
LOS
DS1873
GND
______________________________________________________________________________________
11
DS1873
Block Diagram
SFP+ Controller with Analog LDD Interface
DS1873
Typical Operating Circuit
+3.3V
100Ω
ROSA
LOS
TOSA
LDD
BIAS MON
DISABLE
MOD
DAC
BIAS
DAC
MON1
MON2
EEPROM
TXF
TXD
TXDOUT
QUICK
TRIP
I2C
SDA
SCL
TX_FAULT
TX_DISABLE
MODE_DEF2 (SDA)
MODE_DEF1 (SCL)
ADC
RBD
MON3
RMON
Detailed Description
The DS1873 integrates the control and monitoring functionality required to implement an SFP or SFP+ system.
Key components of the DS1873 are shown in the Block
Diagram and described in subsequent sections.
BIAS DAC/APC Control
The DS1873 controls its laser bias current using its
BIAS DAC and the APC loop. The APC loop’s feedback
to the DS1873 is the monitor diode (MON2) current,
which is converted to a voltage using an external resistor. The feedback is sampled by a comparator and
12
DS1873
LOS
LOS
LOSOUT
LOS
compared to a digital set-point value. The output of the
comparator has three states: up, down, or no-operation. The no-operation state prevents the output from
excessive toggling once steady state is reached. As
long as the comparator output is in either the up or
down states, the bias is adjusted by incrementing and
decrementing the BIAS DAC setting.
The DS1873 has an LUT to allow the APC set point to
change as a function of temperature to compensate for
tracking error (TE). The TE LUT has 36 entries that
determine the APC setting in 4°C windows between
-40°C to +100°C.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
ACRONYM
ADC
AGC
APC
APD
ATB
BM
DAC
LOS
LUT
NV
QT
TE
TIA
ROSA
SEE
SFF
SFF-8472
SFP
SFP+
TOSA
TXP
DEFINITION
On power-up, the DS1873 sets the MOD and BIAS
DACs to 0. After a temperature conversion is completed and if the VCC LO alarm is enabled, an additional
VCC conversion above the customer-defined VCC LO
alarm level is required before the MOD DAC is updated
with the value determined by the temperature conversion and the modulation LUT.
When the MOD DAC is set, the BIAS DAC is set to a
value equal to ISTEP (see Figure 1). The startup algorithm checks if this bias current causes a feedback
voltage above the APC set point, and if not, it continues
increasing the BIAS DAC by ISTEP until the APC setpoint is exceeded. When the APC set point is exceeded, the device begins a binary search to quickly reach
the bias current corresponding to the proper power
level. After the binary search is completed, the APC
integrator is enabled and single LSB steps are used to
tightly control the average power.
Analog-to-Digital Converter
Automatic Gain Control
Automatic Power Control
Avalanche Photodiode
Alarm Trap Bytes
Burst Mode
Digital-to-Analog Converter
Loss of Signal
Lookup Table
Nonvolatile
Quick Trip
Tracking Error
Transimpedance Amplifier
Receiver Optical Subassembly
Shadowed EEPROM
Small Form Factor
The TXP HI, TXP LO, HBAL, and BIAS MAX QT alarms
are masked until the binary search is completed.
However, the BIAS MAX alarm is monitored during this
time to prevent the BIAS DAC from exceeding IBIASMAX.
During the bias current initialization, the BIAS DAC is
not allowed to exceed IBIASMAX. If this occurs during
the ISTEP sequence, then the binary search routine is
Document Defining Register Map of SFPs
and SFFs
Small Form Factor Pluggable
Enhanced SFP
Transmit Optical Subassembly
Transmit Power
VCC
VPOA
tINIT
MOD DAC
tSEARCH
4x ISTEP
APC INTEGRATOR ON
3x ISTEP
BIAS DAC
BINARY SEARCH
2x ISTEP
ISTEP
BIAS SAMPLE
1
2
3
4
5
6
7
8
9
10
11
12
13
Figure 1. Power-Up Timing
______________________________________________________________________________________
13
DS1873
BIAS and MOD Output Control
During Power-Up
Table 1. Acronyms
DS1873
SFP+ Controller with Analog LDD Interface
enabled. If IBIASMAX is exceeded during the binary
search, the next smaller step is activated. ISTEP or
binary increments that would cause the BIAS DAC to
exceed IBIASMAX are not taken. Masking the alarms
until the completion of the binary search prevents false
positive alarms during startup.
ISTEP is programmed by the customer using Table
02h, Register BBh. ISTEP should be programmed to
the maximum safe increase that is allowable during
startup. If this value is programmed too low, the
DS1873 still operates, but it could take significantly
longer for the algorithm to converge and hence to control the average power.
If a fault is detected, and TXD is toggled to reenable
the outputs, the DS1873 powers up following a similar
sequence to an initial power-up. The only difference is
that the DS1873 already has determined the present
temperature, so the tINIT time is not required for the
DS1873 to recall the APC and MOD set points from
EEPROM.
BIAS and MOD DACs as a Function of
Transmit Disable (TXD)
If TXD is asserted (logic 1) during normal operation, the
outputs are disabled within t OFF . When TXD is
deasserted (logic 0), the DS1873 sets the MOD DAC
register with the value associated with the present temperature, and initializes the BIAS DAC using the same
search algorithm as done at startup. When asserted,
soft TXD (TXDC) (Lower Memory, Register 6Eh) would
allow a software control identical to the TXD pin (see
Figure 2).
APC and Quick-Trip Timing
As shown in Figure 3, the DS1873’s input comparator is
shared between the APC control loop and the quick-trip
alarms (TXP HI, TXP LO, LOS LO, and BIAS HI). The
comparator polls the alarms in a multiplexed sequence.
Five of every eight comparator readings are used for
APC loop bias-current control. The other three updates
are used to check the HTXP/LTXP (monitor diode voltage), the HBATH (MON1), and LOS (MON3) signals
against the internal APC, BIAS, and MON3 reference,
respectively. If the last APC comparison was higher
than the APC set point, it makes an HTXP comparison,
and if it is lower, it makes an LTXP comparison.
Depending on the results of the comparison, the corresponding alarms and warnings (TXP HI, TXP LO) are
asserted or deasserted.
The DS1873 has a programmable comparator sample
time based on an internally generated clock to facilitate
a wide variety of external filtering options and time
delays. The UPDATE RATE register (Table 02h,
Register 88h) determines the sampling time. Samples
occur at a regular interval, tREP, which is set at 1.6µs.
Table 2 shows the sample rate options available. Any
quick-trip alarm that is detected by default remains
active until a subsequent comparator sample shows
the condition no longer exists. A second bias current
monitor (BIAS MAX) compares the BIAS DAC’s code to
a digital value stored in the IBIASMAX register. This
comparison is made at every bias current update to
ensure that a high-bias current is quickly detected.
The quick-trip comparator uses a 1.6μs window to sample each input. After an APC comparison that requires
TXD
BIAS DAC
tOFF
tON
MOD DAC SETTING
tOFF
tON
Figure 2. TXD Timing
APC QUICK-TRIP SAMPLE TIMES
HBIAS
SAMPLE
APC
SAMPLE
APC
SAMPLE
APC
SAMPLE
APC
SAMPLE
APC
SAMPLE
HTXP/LTXP
SAMPLE
LOS
SAMPLE
HBIAS
SAMPLE
tREP
Figure 3. APC Loop and Quick-Trip Sample Timing
14
______________________________________________________________________________________
APC
SAMPLE
SFP+ Controller with Analog LDD Interface
Monitors and Fault Detection
Monitors
Monitoring functions on the DS1873 include five quicktrip comparators and six ADC channels. This monitoring combined with the alarm enables (Table 01h/05h)
determines when/if the DS1873 turns off the MOD and
BIAS DACs and triggers the TXF and TXDOUT outputs.
All the monitoring levels and interrupt masks are user
programmable.
Five Quick-Trip Monitors and Alarms
Five quick-trip monitors are provided to detect potential
laser safety issues and LOS status. These monitor the
following:
1) High Bias Current (HBATH)
2) Low Transmit Power (LTXP)
3) High Transmit Power (HTXP)
4) Max Output Current (IBIASMAX)
5) Loss-of-Signal (LOS LO)
The high-transmit and low-transmit power quick-trip
registers (HTXP and LTXP) set the thresholds used to
compare against the MON2 voltage to determine if the
transmit power is within specification. The HBATH
quick trip compares the MON1 input (generally from the
laser driver’s bias monitor output) against its threshold
setting to determine if the present bias current is above
specification. The BIAS MAX quick trip determines if the
BIAS DAC is above specification (IBIASMAX). When the
new BIAS DAC value is calculated, it is compared
against the IBIAS MAX register. The BIAS DAC is not
allowed to exceed the value set in the IBIASMAX register. When the DS1873 detects that the bias is at the
limit, it sets the BIASMAX status bit and holds the BIAS
DAC setting at the IBIASMAX level. The bias and power
quick trips are routed to the TXF through interrupt
masks to allow combinations of these alarms to be
used to trigger these outputs. The user can program up
to eight different temperature-indexed threshold levels
for MON1 (Table 02h, Registers D0h–D7h). The LOS
LO quick trip compares the MON3 input against its
threshold setting to determine if the present received
power is below the specification. The LOS LO quick trip
can be used to set the LOSOUT pin.
Six ADC Monitors and Alarms
The ADC monitors six channels that measure temperature (internal temp sensor), VCC, and MON1–MON4
using an analog multiplexer to measure them round
robin with a single ADC (see the ADC Timing section).
The five voltage channels have a customer-programmable full-scale range and all channels have a customer-programmable offset value that is factory
programmed to default value (see Table 2).
Additionally, MON1–MON4 can right-shift results by up
to 7 bits before the results are compared to alarm
thresholds or read over the I2C bus. This allows customers with specified ADC ranges to calibrate the ADC
full scale to a factor of 1/2n of their specified range to
measure small signals. The DS1873 can then right-shift
the results by n bits to maintain the bit weight of their
specification (see the Right-Shifting ADC Result and
Enhanced RSSI Monitoring (Dual-Range Functionality)
sections).
Table 2. ADC Default Monitor Full-Scale
Ranges
+FS
SIGNAL
+FS
hex
-FS
SIGNAL
Temperature (°C)
127.996
7FFF
-128
8000
VCC (V)
6.5528
FFF8
0
0000
MON1–MON4 (V)
2.4997
FFF8
0
0000
SIGNAL
-FS
hex
The ADC results (after right-shifting, if used) are compared to the alarm and warning thresholds after each
conversion, and the corresponding alarms are set,
which can be used to trigger the TXF output. These
ADC thresholds are user programmable, as are the
masking registers that can be used to prevent the
alarms from triggering the TXF output.
ADC Timing
There are six analog channels that are digitized in a
round-robin fashion in the order shown in Figure 4. The
total time required to convert all six channels is tRR (see
the Electrical Characteristics for details).
Right-Shifting ADC Result
If the weighting of the ADC digital reading must conform to a predetermined full-scale (PFS) value defined
by a standard’s specification (e.g., SFF-8472), then
right-shifting can be used to adjust the PFS analog
measurement range while maintaining the weighting of
______________________________________________________________________________________
15
DS1873
an update to the BIAS DAC, a settling time (as calculated below) is required to allow for the feedback on BMD
(MON2) to stabilize. This time is dependent on the time
constant of the filter pole used for the delta-to-sigma
BIAS output. During the timing of the settling rate, comparisons of APC comparisons of BMD are ignored until
32 sample periods (tREP) have passed.
SettlingTime = 51.2µs x (APC_SR[3:0] + 1)
DS1873
SFP+ Controller with Analog LDD Interface
ONE ROUND-ROBIN ADC CYCLE
TEMP
VCC
MON1
MON2
MON3
MON4
TEMP
tRR
NOTE: IF THE VCC LO ALARM IS ENABLED AT POWER-UP, THE ADC ROUND-ROBIN TIMING CYCLES BETWEEN TEMPERATURE AND VCC ONLY UNTIL VCC
IS ABOVE THE VCC ALARM LOW THRESHOLD.
Figure 4. ADC Round-Robin Timing
Figure 5. This reduces board complexity by eliminating
the need for a high-side differential amplifier or a current mirror.
VCC
MON3P
DS1873
ADC
100Ω
MON3N
ROSA
Figure 5. MON3 Differential Input for High-Side RSSI
the ADC results. The DS1873’s range is wide enough to
cover all requirements; when the maximum input value
is ≤ 1/2 of the FS value, right-shifting can be used to
obtain greater accuracy. For instance, the maximum
voltage might be 1/8 the specified PFS value, so only
1/8 the converter’s range is effective over this range.
An alternative is to calibrate the ADC’s full-scale range
to 1/8 the readable PFS value and use a right-shift
value of 3. With this implementation, the resolution of
the measurement is increased by a factor of 8, and
because the result is digitally divided by 8 by rightshifting, the bit weight of the measurement still meets
the standard’s specification (i.e., SFF-8472).
The right-shift operation on the ADC result is carried out
based on the contents of right-shift control registers
(Table 02h, Registers 8Eh–8Fh) in EEPROM. Four analog channels, MON1–MON4, each have 3 bits allocated
to set the number of right-shifts. Up to 7 right-shift operations are allowed and are executed as a part of every
conversion before the results are compared to the highalarm and low-alarm levels, or loaded into their corresponding measurement registers (Lower Memory,
Registers 64h–6Bh). This is true during the setup of
internal calibration as well as during subsequent data
conversions.
Differential MON3 Input
The DS1873 offers a fully differential input for MON3.
This enables high-side monitoring of RSSI, as shown in
16
Enhanced RSSI Monitoring (Dual-Range
Functionality)
The DS1873 offers a feature to improve the accuracy
and range of MON3, which is most commonly used for
monitoring RSSI. The accuracy of the RSSI measurements is increased at the small cost of reduced range
(of input signal swing). The DS1873 eliminates this
trade-off by offering “dual range” calibration on the
MON3 channel (see Figure 5). This feature enables
right-shifting (along with its gain and offset settings)
when the input signal is below a set threshold (within the
range that benefits using right-shifting) and then automatically disables right-shifting (recalling different gain and
offset settings) when the input signal exceeds the threshold. Also, to prevent “chattering,” hysteresis prevents
excessive switching between modes in addition to ensuring that continuity is maintained. Dual-range operation is
enabled by default (factory programmed in EEPROM).
However, it can easily be disabled through the RSSI_FC
and RSSI_FF bits, which are described in the Register
Descriptions section. When dual-range operation is disabled, MON3 operates identically to the other MON
channels, although featuring a differential input.
Dual-range functionality consists of two modes of operation: fine mode and coarse mode. Each mode is calibrated for a unique transfer function, hence the term, dual
range. Table 4 highlights the registers related to MON3.
Fine mode is equivalent to the other MON channels. Fine
mode is calibrated using the gain, offset, and right-shifting registers at locations shown in Table 4 and is ideal
for relatively small analog input voltages. Coarse mode is
automatically switched to when the input exceeds a
threshold (to be discussed in a subsequent paragraph).
Coarse mode is calibrated using different gain and offset
registers, but lacks right-shifting (since coarse mode is
only used on large input signals). The gain and offset
registers for coarse mode are also shown in Table 4.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
MON3
TIMESLICE
NUMBER OF
RIGHT-SHIFTS
PERFORM FINEMODE CONVERSION
DID PRIOR MON3
TIMESLICE RESULT IN A
COARSE CONVERSION?
(LAST RSSI = 1?)
Y
N
N
DID CURRENT FINEMODE CONVERSION
REACH MAX?
Y
WAS CURRENT FINEMODE CONVERSION
≥ 93.75% OF FS?
Y
N
LAST RSSI = 1
REPORT FINE
CONVERSION RESULT
COARSE MODE
MIN* (hex)
0
FFF8
F000
1
7FFC
7800
2
3FFE
3C00
3
1FFF
1E00
4
0FFF
0F00
5
07FF
0780
6
03FF
03C0
7
01FF
01E0
*This is the minimum reported coarse-mode conversion.
Table 4. MON3 Configuration Registers
REGISTER
GAIN
PERFORM COARSEMODE CONVERSION
LAST RSSI = 0
FINE MODE
MAX (hex)
OFFSET
RIGHT-SHIFT0
FINE MODE
COARSE MODE
98h–99h, Table 02h
9Ch–9Dh, Table 04h
A8h–A9h, Table 02h ADh–ACh, Table 04h
8Fh, Table 04h
—
CNFGC
8Bh, Table 02h
CONFIG
(RSSIS BIT)
77h, Lower Memory
MON3 VALUE
68h–69h, Lower Memory
REPORT COARSE
CONVERSION RESULT
END OF MON3
TIMESLICE
Figure 6. RSSI Flowchart
Additional information for each of the registers can be
found in the Register Descriptions section.
Dual-range operation is transparent to the end user.
The results of MON3 analog-to-digital conversions are
still stored/reported in the same memory locations
(68h–69h, Lower Memory) regardless of whether the
conversion was performed in fine mode or coarse
mode. The only way to tell which mode generated the
digital result is by reading the RSSIS bit.
When the DS1873 is powered up, analog-to-digital conversions begin in a round-robin fashion. Every MON3
timeslice begins with a fine mode analog-to-digital conversion (using fine mode’s gain, offset, and right-shifting
settings). See the flowchart in Figure 6 for more details.
Then, depending on whether the last MON3 timeslice
resulted in a coarse-mode conversion and also depending on the value of the current fine conversion, decisions
are made whether to use the current fine-mode conversion result or to make an additional conversion (within
the same MON3 timeslice), using coarse mode (using
coarse mode’s gain and offset settings and no rightshifting) and reporting the coarse-mode result. The flowchart in Figure 6 also illustrates how hysteresis is
implemented. The fine-mode conversion is compared to
one of two thresholds. The actual threshold values are a
function of the number of right-shifts being used. With
the use of right-shifting, the fine mode full-scale is programmed to (1/2Nth) of the coarse mode full-scale. The
DS1873 now auto ranges to choose the range that gives
the best resolution for the measurement. Hysteresis is
applied to eliminate chatter when the input resides at
the boundary of the two ranges. See Figure 6 for details.
Table 3 shows the threshold values for each possible
number of right-shifts.
______________________________________________________________________________________
17
DS1873
Table 3. MON3 Hysteresis Threshold
Values
The RSSI_FF and RSSI_FC bits are used to force finemode or coarse-mode conversions, or to disable the
dual-range functionality. Dual-range functionality is
enabled by default (both RSSI_FC and RSSI_FF are
factory programmed to 0 in EEPROM). It can be disabled by setting RSSI_FC to 0 and RSSI_FF to 1. These
bits are also useful when calibrating MON3. For additional information, see Figure 18. The dual-range calibration can operate in two modes: crossover enabled
and crossover disabled.
• Crossover Enabled: For systems with nonlinear
relationships between the ADC input and the desired
ADC result, the mode should be set to crossover
enabled. The RSSI measurement of an APD receiver
is one such application. Using the crossoverenabled mode allows a piecewise linear approxima-
tion of the nonlinear response of the APD’s gain factor. The crossover point is the point between fine and
coarse points. The ADC result transitions between
the fine and coarse ranges with no hysteresis. Rightshifting, slope adjustment, and offset are configurable for both the fine and coarse ranges. See
Figure 7.
• Crossover Disabled: The crossover-disabled mode
is intended for systems with a linear relationship
between the MON3 input and the desired ADC
result. Hysteresis allows for a nonjittery response
when the input is at the crossover boundary of the
fine and coarse DAC. In a nonlinear system, the hysteresis could cause significant errors in the ADC
result. See Figure 8.
RSSI RESULT
CROSSOVER POINT
IDEAL RESPONSE
MON3 INPUT
Figure 7. RSSI with Crossover Enabled
PON
SE
RSSI RESULT
RES
ALE
L-SC
FUL
T=
HIF
S
HT-
3
IG
ER
FIN
SE
AR
CO
L
CA
L-S
L
FU
ES
ER
E
NS
PO
FINE
DS1873
SFP+ Controller with Analog LDD Interface
HYSTERESIS
MON3 INPUT
FINE
COARSE
Figure 8. RSSI with Crossover Disabled
18
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
For all device addresses sourced from EEPROM (Table
02h, Register 8Ch), the default device address is A2h
until VCC exceeds POA, allowing the device address to
be recalled from the EEPROM.
Power-On Analog (POA)
POA holds the DS1873 in reset until VCC is at a suitable
level (VCC > POA) for the device to accurately measure
with its ADC and compare analog signals with its quicktrip monitors. Because VCC cannot be measured by the
ADC when VCC is less than POA, POA also asserts the
VCC LO alarm, which is cleared by a VCC ADC conversion greater than the customer-programmable V CC
alarm LO ADC limit. This allows a programmable limit to
ensure that the headroom requirements of the transceiver are satisfied during a slow power-up. The TXF
output does not latch until there is a conversion above
VCC low limit. The POA alarm is nonmaskable. The TXF
output is asserted when VCC is below POA. See the
Low-Voltage Operation section for more information.
Delta-Sigma Outputs
Four delta-sigma outputs are provided: MOD DAC,
BIAS DAC, DAC1, and DAC2. With the addition of an
external RC filter, these outputs provide 10-bit resolution analog outputs with the full-scale range set by the
input REFIN. Each output is either manually controlled
or controlled using a temperature-indexed LUT, or in
the case of the BIAS DAC, controlled by the APC loop.
A delta-sigma is a digital output using pulse-density
modulation. It provides much lower output ripple than a
SEE RECALL
SEE RECALL
VPOA
VCC
VPOD
SEE
PRECHARGED
TO 0
RECALLED VALUE
PRECHARGED TO 0
RECALLED VALUE
PRECHARGED
TO 0
Figure 9. Low-Voltage Hysteresis Example
______________________________________________________________________________________
19
DS1873
Low-Voltage Operation
The DS1873 contains two power-on reset (POR) levels.
The lower level is a digital POR (POD) and the higher
level is an analog POR (POA). At startup, before the
supply voltage rises above POA, the outputs are disabled, all SRAM locations are set to their defaults,
shadowed EEPROM (SEE) locations are zero, and all
analog circuitry is disabled. When VCC reaches POA,
the SEE is recalled, and the analog circuitry is enabled.
While VCC remains above POA, the device is in its normal operating state, and it responds based on its nonvolatile configuration. If during operation V CC falls
below POA, but is still above POD, then the SRAM
retains the SEE settings from the first SEE recall, but the
device analog is shut down and the outputs disabled. If
the supply voltage recovers back above POA, then the
device immediately resumes normal operation. If the
supply voltage falls below POD, then the device SRAM
is placed in its default state and another SEE recall is
required to reload the nonvolatile settings. The EEPROM recall occurs the next time VCC exceeds POA.
Figure 8 shows the sequence of events as the voltage
varies.
Any time VCC is above POD, the I2C interface can be
used to determine if VCC is below the POA level. This is
accomplished by checking the RDYB bit in the STATUS
(Lower Memory, Register 6Eh) byte. RDYB is set when
VCC is below POA; when VCC rises above POA, RDYB
is timed (within 500µs) to go to 0, at which point the
part is fully functional.
DS1873
SFP+ Controller with Analog LDD Interface
3.24kΩ
3.24kΩ
DAC
OUTPUT
0.01μF
0.01μF
DS1873
Figure 10. Recommended RC Filter for DAC1/DAC2
standard digital PWM output given the same clock rate
and filter components. Before tINIT, the DAC outputs
are high impedance.
The external RC filter components are chosen based
on ripple requirements, output load, delta-sigma frequency, and desired response time. A recommended
filter is shown in Figure 10.
The DS1873’s delta-sigma outputs are 10 bits. For illustrative purposes, a 3-bit example is provided. Each
possible output of this 3-bit delta-sigma DAC is given in
Figure 11.
In LUT mode, MOD, DAC1, and DAC2 are each controlled by an LUT with high-temperature resolution and
an OFFSET LUT with lower temperature resolution. The
MOD and DAC1 high-resolution LUTs each have 2°C
resolution. The DAC2 high-resolution LUT has 4°C resolution. The OFFSET LUTs are located in the upper eight
registers (F8h–FFh) of the table containing each highresolution LUT. MOD DAC, DAC1 VALUE, and DAC2
VALUE are determined as follows:
MOD DAC = MOD LUT + 4 x (MOD OFFSET LUT)
DAC1 VALUE = DAC1 LUT + 4 x (DAC1 OFFSET LUT)
DAC2 VALUE = DAC1 LUT + 4 x (DAC1 OFFSET LUT)
Example calculation for MOD DAC:
Assumptions:
1) Temperature is 43°C.
2) Table 04h (MOD OFFSET LUT), Register FCh = 2Ah.
3) Table 04h (MOD LUT), Register A9h = 7Bh.
Because the temperature is 43°C, the MOD LUT index
is A9h and the MOD OFFSET LUT index is FCh.
MOD DAC = 7Bh + 4 x 2Ah = 123h = 291
When temperature controlled, the DACs are updated
after each temperature conversion.
The reference input, REFIN, is the supply voltage for all
four DACs. The voltage connected to REFIN and its
decoupling must be able to support the edge rate
requirements of the delta-sigma outputs.
0
1
2
3
4
5
6
7
Figure 11. 3-Bit Delta-Sigma Example
20
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
EACH OFFSET REGISTER CAN BE INDEPENDENTLY
SET BETWEEN 0 AND 1020. 1020 = 4 x FFh. THIS
EXAMPLE ILLUSTRATES POSITIVE TEMPCO.
FDh
767
FCh
FBh
511
FAh
F9h
F8h
255
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
MOD, DAC1, AND DAC2 OFFSET LUTs (04h, 07h, AND 08h)
EIGHT REGISTERS PER DAC
FFh
FEh
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
0
1023
DELTA-SIGMA MOD, DAC1, AND DAC2
DELTA-SIGMA MOD, DAC1, AND DAC2
1023
DS1873
MOD, DAC1, AND DAC2 OFFSET LUTs (04h, 07h, AND 08h)
EIGHT REGISTERS PER DAC
EACH OFFSET REGISTER CAN BE INDEPENDENTLY SET BETWEEN
0 AND 1020. 1020 = 4 x FFh. THIS EXAMPLE ILLUSTRATES POSITIVE
AND NEGATVE TEMPCO.
767
FCh
FBh
FAh
F9h
511
F8h
255
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
DAC
LUT
BITS
7:0
FDh
DAC
LUT
BITS
7:0
FEh
DAC
LUT
BITS
7:0
FFh
DAC
LUT
BITS
7:0
0
-40°C
-8°C
+8°C
+24°C +40°C +56°C +70°C +88°C +104°C
-40°C
-8°C
+8°C
+24°C +40°C +56°C +70°C +88°C +104°C
Figure 12. MOD, DAC1, and DAC2 Offset LUTs
Digital I/O Pins
Five digital input and five digital output pins are provided for monitoring and control.
LOS, LOSOUT
By default (LOSC = 1, Table 02h, Register 89h), the
LOS pin is used to convert a standard comparator output for loss of signal (LOS) to an open-collector output.
This means the mux shown in the Block Diagram by
default selects the LOS pin as the source for the
LOSOUT output transistor. The output of the mux can
be read in the STATUS byte (Table 01h, Register 6Eh)
as the RXL bit. The RXL signal can be inverted (INV
LOS = 1) before driving the open-drain output transistor
using the XOR gate provided. Setting LOSC = 0 configures the mux to be controlled by LOS LO, which is driven by the output of the LOS quick trip (Table 02h,
Registers BEh and BFh). The mux setting (stored in
EEPROM) does not take effect until VCC > POA, allowing the EEPROM to recall.
IN1, RSEL, OUT1, RSELOUT
The digital input IN1 and RSEL pins primarily serve to
meet the rate-select requirements of SFP and SFP+.
They also serve as general-purpose inputs. OUT1 and
RSELOUT are driven by a combination of the IN1,
RSEL, and logic dictated by control registers in the
EEPROM (Figure 14). The levels of IN1 and RSEL can
be read using the STATUS register (Lower Memory,
Register 6Eh). The open-drain output OUT1 can be
controlled and/or inverted using the CNFGB register
(Table 02h, Register 8Ah). The open-drain RSELOUT
output is software-controlled and/or inverted through
the STATUS register and CNFGA register (Table 02h,
Register 89h). External pullup resistors must be provided on OUT1 and RSELOUT to realize high logic levels.
______________________________________________________________________________________
21
DS1873
SFP+ Controller with Analog LDD Interface
VCC
RPU
TXDS
SET BIAS DAC AND
MOD DAC TO 0
TXD
C
TXDC
R
Q
TXDFG
C
D
TXDOUT
FETG
Q
TXP HI FLAG
TXD
TXDIO
S
TXDFLT
TXP HI ENABLE
TXF
BIAS MAX
TXF
BIAS MAX ENABLE
HBAL FLAG
MINT
HBAL FLAG
TXP LO FLAG
TXP HI FLAG
BIAS MAX FLAG
HBAL ENABLE
TXP LO FLAG
TXP LO ENABLE
TXDEXT
FAULT RESET TIMER
(130ms)
OUT
IN
IN
POWER-ON
RESET
= PINS
OUT
Figure 13. Logic Diagram 1
TXF, TXD, TXDOUT
TXDOUT is generated from a combination of TXF, TXD,
and the internal signal FETG. A software control identical
to TXD is available (TXDC, Lower Memory, Register
6Eh). A TXD pulse is internally extended (TXDEXT) by
time tINITR1 to inhibit the latching of low alarms and
warnings related to the APC loop to allow for the loop to
stabilize. The nonlatching alarms and warnings are TXP
LO, LOS LO, and MON1–MON4 LO alarms and warnings. In addition, TXP LO is disabled from creating FETG.
TXF is both an input and an output (Figure 13). See the
Transmit Fault (TXF) Output section for a detailed explanation of TXF. Figure 13 shows that the same signals and
faults can also be used to generate the internal signal
FETG (Table 01h/05h, Registers FAh and FBh). FETG is
used to send a fast “turn-off” command to the laser driver. The intended use is a direct connection to the laser
driver’s TXD input if this is desired. When VCC < POA,
TXDOUT is high impedance.
IN1S
OUT1
INVOUT1
IN1C
IN1
RSELS
RSELOUT
RSELC
RSEL
LOSC
INV LOS
LOSOUT
LOS
MUX
LOS LO
RXL
= PINS
Figure 14. Logic Diagram 2
22
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
DS1873
DETECTION OF TXFOUT FAULT
TXFOUT
Figure 15a. TXF Nonlatched Operation
DETECTION OF TXFOUT FAULT
TXD OR TXFOUT RESET
TXFOUT
Figure 15b. TXF Latched Operation
Transmit Fault (TXF) Output
TXF can be triggered by all alarms, warnings, and
quick trips (Figure 13). The six ADC alarms, warnings,
and the LOS quick trips require enabling (Table
01h/05h, Registers F8h and FDh). See Figures 15a and
15b for nonlatched and latched operation. Latching of
the alarms is controlled by the CNFGB and CNFGC
registers (Table 02h, Registers 8Ah–8Bh).
Die Identification
The DS1873 has an ID hardcoded in its die. Two registers (Table 02h, Registers CEh–CFh) are assigned for
this feature. The CEh register reads 73h to identify the
part as the DS1873, while the CFh register reads the
current device version.
I2C Communication
I2C Definitions
The following terminology is commonly used to
describe I2C data transfers.
Master device: The master device controls the
slave devices on the bus. The master device generates SCL clock pulses and START and STOP
conditions.
Slave devices: Slave devices send and receive
data at the master’s request.
Bus idle or not busy: Time between STOP and
START conditions when both SDA and SCL are inactive and in their logic-high states.
START condition: A START condition is generated
by the master to initiate a new data transfer with a
slave. Transitioning SDA from high to low while SCL
remains high generates a START condition. See
Figure 16 for applicable timing.
STOP condition: A STOP condition is generated by
the master to end a data transfer with a slave.
Transitioning SDA from low to high while SCL
remains high generates a STOP condition. See
Figure 16 for applicable timing.
Repeated START condition: The master can use a
repeated START condition at the end of one data
transfer to indicate that it will immediately initiate a
new data transfer following the current one.
Repeated STARTs are commonly used during read
operations to identify a specific memory address to
begin a data transfer. A repeated START condition
is issued identically to a normal START condition.
See Figure 16 for applicable timing.
______________________________________________________________________________________
23
DS1873
SFP+ Controller with Analog LDD Interface
Bit write: Transitions of SDA must occur during the
low state of SCL. The data on SDA must remain valid
and unchanged during the entire high pulse of SCL
plus the setup and hold time requirements (Figure
16). Data is shifted into the device during the rising
edge of the SCL.
Bit read: At the end a write operation, the master
must release the SDA bus line for the proper amount
of setup time (Figure 16) before the next rising edge
of SCL during a bit read. The device shifts out each
bit of data on SDA at the falling edge of the previous
SCL pulse and the data bit is valid at the rising edge
of the current SCL pulse. Remember that the master
generates all SCL clock pulses, including when it is
reading bits from the slave.
significant bit first) plus a 1-bit acknowledgement
from the slave to the master. The 8 bits transmitted
by the master are done according to the bit-write
definition and the acknowledgement is read using
the bit-read definition.
Byte read: A byte read is an 8-bit information transfer from the slave to the master plus a 1-bit ACK or
NACK from the master to the slave. The 8 bits of
information that are transferred (most significant bit
first) from the slave to the master are read by the
master using the bit-read definition, and the master
transmits an ACK using the bit-write definition to
receive additional data bytes. The master must
NACK the last byte read to terminate communication
so the slave returns control of SDA to the master.
Acknowledgement (ACK and NACK): An acknowledgement (ACK) or not acknowledge (NACK) is
always the ninth bit transmitted during a byte transfer. The device receiving data (the master during a
read or the slave during a write operation) performs
an ACK by transmitting a zero during the ninth bit. A
device performs a NACK by transmitting a one during the 9th bit. Timing (Figure 16) for the ACK and
NACK is identical to all other bit writes. An ACK is
the acknowledgment that the device is properly
receiving data. A NACK is used to terminate a read
sequence or as an indication that the device is not
receiving data.
Byte write: A byte write consists of 8 bits of information transferred from the master to the slave (most
Slave address byte: Each slave on the I 2C bus
responds to a slave address byte sent immediately
following a START condition. The slave address byte
contains the slave address in the most significant 7
bits and the R/W bit in the least significant bit.
The DS1873 responds to two slave addresses. The
auxiliary memory always responds to a fixed I2C
slave address, A0h. The Lower Memory and Tables
00h–08h respond to I2C slave addresses that can
be configured to any value between 00h–FEh using
the DEVICE ADDRESS byte (Table 02h, Register
8Ch). The user also must set the ASEL bit (Table
02h, Register 89h) for this address to be active. By
writing the correct slave address with R/W = 0, the
master indicates it will write data to the slave. If R/W
SDA
tBUF
tF
tHD:STA
tLOW
tSP
SCL
tHIGH
tHD:STA
tHD:DAT
STOP
tSU:STA
tR
START
tSU:DAT
REPEATED
START
NOTE: TIMING IS REFERENCED TO VIL(MAX) AND VIH(MIN).
Figure 16. I2C Timing
24
______________________________________________________________________________________
tSU:STO
SFP+ Controller with Analog LDD Interface
writes the memory address, writes up to 8 data
bytes, and generates a STOP condition. The
DS1873 writes 1 to 8 bytes (one page or row) with a
single write transaction. This is internally controlled
by an address counter that allows data to be written
to consecutive addresses without transmitting a
memory address before each data byte is sent. The
address counter limits the write to one 8-byte page
(one row of the memory map). Attempts to write to
additional pages of memory without sending a STOP
condition between pages results in the address
counter wrapping around to the beginning of the
present row.
For example, a 3-byte write starts at address 06h
and writes three data bytes (11h, 22h, and 33h) to
three “consecutive” addresses. The result is that
addresses 06h and 07h would contain 11h and 22h,
respectively, and the third data byte, 33h, would be
written to address 00h.
I2C Protocol
Writing a single byte to a slave: The master must
generate a START condition, write the slave address
byte (R/W = 0), write the memory address, write the
byte of data, and generate a STOP condition.
Remember the master must read the slave’s
acknowledgement during all byte-write operations.
Writing multiple bytes to a slave: To write multiple
bytes to a slave, the master generates a START condition, writes the slave address byte (R/W = 0),
To prevent address wrapping from occurring, the
master must send a STOP condition at the end of
the page, then wait for the bus-free or EEPROM
write time to elapse. Then the master can generate a
new START condition and write the slave address
TYPICAL I2C WRITE TRANSACTION
MSB
START
1
MSB
LSB
0
1
0
0
0
SLAVE
ADDRESS*
1
R/W
SLAVE
ACK
b7
LSB
b6
b5
b4
b3
b2
b1
MSB
SLAVE
ACK
b0
b7
LSB
b6
b5
b4
REGISTER ADDRESS
READ/
WRITE
b3
b2
b1
b0
SLAVE
ACK
STOP
DATA
*IF ASEL IS 0, THE SLAVE ADDRESS IS A0h FOR THE AUXILIARY MEMORY AND A2h FOR THE MAIN MEMORY.
IF ASEL = 1, THE SLAVE ADDRESS IS DETERMINED BY TABLE 02h, REGISTER 8Ch FOR THE MAIN MEMORY. THE AUXILIARY MEMORY CONTINUES TO BE ADDRESSED AT A0h, EXCEPT WHEN THE PROGRAMMED
ADDRESS FOR THE MAIN MEMORY IS A0h.
EXAMPLE I2C TRANSACTIONS WITH A2h AS THE MAIN MEMORY DEVICE ADDRESS
A2h
A) SINGLE-BYTE WRITE
-WRITE 00h TO REGISTER BAh
B) SINGLE-BYTE READ
-READ REGISTER BAh
C) TWO-BYTE WRITE
-WRITE C8h AND C9h
TO 01h AND 75h
START 1 0 1 0 0 0 1 0
A2h
BAh
START 1 0 1 0 0 0 1 0 SLAVE 1 0 1 1 1 0 1 0 SLAVE
ACK
ACK
REPEATED
START
STOP
A3h
1 0 1 0 0 0 1 1 SLAVE
ACK
DATA
DATA IN BAh
A2h
C8h
01h
75h
START 1 0 1 0 0 0 1 0 SLAVE 1 1 0 0 1 0 0 0 SLAVE 0 0 0 0 0 0 0 1 SLAVE 0 1 1 1 0 1 0 1 SLAVE
ACK
ACK
ACK
ACK
A2h
D) TWO-BYTE READ
-READ C8h AND C9h
BAh
00h
SLAVE
SLAVE
SLAVE
ACK 1 0 1 1 1 0 1 0 ACK 0 0 0 0 0 0 0 0 ACK
START 1 0 1 0 0 0 1 0
C8h
SLAVE
SLAVE
1
1
0
0 1 0 0 0 ACK
ACK
A3h
REPEATED
START
10100011
MASTER
NACK
STOP
MASTER
NACK
DATA IN C9h
STOP
DATA
SLAVE
ACK
DATA IN C8h
DATA
MASTER
NACK
STOP
Figure 17. Example I2C Timing
______________________________________________________________________________________
25
DS1873
= 1, the master reads data from the slave. If an
incorrect slave address is written, the DS1873
assumes the master is communicating with another
I2C device and ignores the communications until the
next START condition is sent. If the main device’s
slave address is programmed to be A0h, access to
the auxiliary memory is disabled.
Memory address: During an I2C write operation to
the DS1873, the master must transmit a memory
address to identify the memory location where the
slave is to store the data. The memory address is
always the second byte transmitted during a write
operation following the slave address byte.
SFP+ Controller with Analog LDD Interface
DS1873
byte (R/W = 0) and the first memory address of the
next memory row before continuing to write data.
Acknowledge polling: Any time a EEPROM page is
written, the DS1873 requires the EEPROM write time
(tW) after the STOP condition to write the contents of
the page to EEPROM. During the EEPROM write
time, the DS1873 will not acknowledge its slave
address because it is busy. It is possible to take
advantage of that phenomenon by repeatedly
addressing the DS1873, which allows the next page
to be written as soon as the DS1873 is ready to
receive the data. The alternative to acknowledge
polling is to wait for maximum period of tW to elapse
before attempting to write again to the DS1873.
EEPROM write cycles: When EEPROM writes occur,
the DS1873 writes the whole EEPROM memory page,
even if only a single byte on the page was modified.
Writes that do not modify all 8 bytes on the page are
allowed and do not corrupt the remaining bytes of
memory on the same page. Because the whole page
is written, bytes on the page that were not modified
during the transaction are still subject to a write
cycle. This can result in a whole page being worn out
over time by writing a single byte repeatedly. Writing
a page one byte at a time wears the EEPROM out
eight times faster than writing the entire page at
once. The DS1873’s EEPROM write cycles are specified in the Nonvolatile Memory Characteristics table.
The specification shown is at the worst-case temperature. It can handle approximately ten times that
many writes at room temperature. Writing to SRAMshadowed EEPROM memory with SEEB = 1 does not
count as an EEPROM write cycle when evaluating
the EEPROM’s estimated lifetime.
Reading a single byte from a slave: Unlike the
write operation that uses the memory address byte
to define where the data is to be written, the read
operation occurs at the present value of the memory
address counter. To read a single byte from the
slave, the master generates a START condition,
writes the slave address byte with R/W = 1, reads
the data byte with a NACK to indicate the end of the
transfer, and generates a STOP condition.
Manipulating the address counter for reads: A
dummy write cycle can be used to force the address
pointer to a particular value. To do this, the master
generates a START condition, writes the slave
address byte (R/W = 0), writes the memory address
where it desires to read, generates a repeated
26
START condition, writes the slave address byte (R/W
= 1), reads data with ACK or NACK as applicable,
and generates a STOP condition.
Memory Organization
The DS1873 features nine separate memory tables that
are internally organized into 8-byte rows.
The DS1873 has two passwords that are each 4 bytes
long. The lower level password (PW1) has all the
access of a normal user plus those made available with
PW1. The higher level password (PW2) has all the
access of PW1 plus those made available with PW2.
The values of the passwords reside in EEPROM inside
of PW2 memory. At power-up, all PWE bits are set to 1,
and all reads at this location are 0.
The Lower Memory is addressed from 00h to 7Fh and
contains alarm and warning thresholds, flags, masks,
several control registers, password entry area (PWE),
and the table-select byte.
Table 01h primarily contains user EEPROM (with PW1
level access) as well as alarm and warning-enable
bytes.
Table 02h is a multifunction space that contains configuration registers, scaling and offset values, passwords,
interrupt registers as well as other miscellaneous control bytes.
Table 04h contains a temperature-indexed LUT for
control of the modulation output. The modulation LUT
can be programmed in 2°C increments over the -40°C
to +102°C range. The table also contains a temperature-indexed LUT for MOD offsets.
Table 05h is empty by default. It can be configured to
contain the alarm- and warning-enable bytes from Table
01h, Registers F8h–FFh with the MASK bit enabled
(Table 02h, Register 89h). In this case Table 01h is
empty.
Table 06h contains a temperature-indexed LUT that
allows the APC set point to change as a function of
temperature to compensate for tracking error (TE). The
APC LUT has 36 entries that determine the APC setting
in 4°C windows between -40°C and +100°C. The table
also contains a temperature-indexed LUT for HBIAS
thresholds.
Table 07h contains a temperature-indexed LUT for control of DAC1. The LUT has 72 entries that determine the
DAC setting in 4°C windows between -40°C and
+100°C. The table also contains a temperature-indexed
LUT for DAC1 offsets.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
Shadowed EEPROM
Many NV memory locations (listed within the Register
Descriptions section) are actually shadowed EEPROM
that are controlled by the SEEB bit in Table 02h,
Register 80h.
I2C ADDRESS A0h
I2C ADDRESS A2h (DEFAULT)
00h
00h
LOWER
MEMORY
NOTE 1: IF ASEL = 0, THEN THE MAIN DEVICE I2C SLAVE ADDRESS IS A2h.
IF ASEL = 1, THEN THE MAIN DEVICE I2C SLAVE ADDRESS IS DETERMINED BY THE VALUE IN
TABLE 02h, REGISTER 8Ch.
NOTE 2: TABLE 00h DOES NOT EXIST.
NOTE 3: ALARM-ENABLE ROW CAN BE CONFIGURED TO EXIST AT TABLE 01h OR TABLE 05h USING THE
MASK BIT IN TABLE 02h, REGISTER 89h.
MAIN DEVICE
EEPROM
(256 BYTES)
AUXILIARY DEVICE
PASSWORD ENTRY
(PWE) (4 BYTES)
TABLE-SELECT
BYTE 7Fh
80h
80h
TABLE 01h
EEPROM
(120 BYTES)
F7h
F8h
FFh
ALARMENABLE ROW
(8 BYTES) FFh
80h
TABLE 02h
NONLOOKUP
TABLE CONTROL
AND
CONFIGURATION
REGISTERS
TABLE 04h
MOD
LOOKUP TABLE
(72 BYTES)
80h
F8h
F8h
DAC1 OFFSET
LUT
FFh
MOD OFFSET
LUT
FFh
80h
TABLE 08h
DAC2 LUT
TABLE 07h
DAC1 LUT
A3h
C7h
C7h
F8h
FFh
80h TABLE 06h
TRACKING ERROR
LOOKUP TABLE
(36 BYTES) A3h
F8h TABLE 05h
ALARM-ENABLE ROW
(8 BYTES) FFh
HBIAS LUT
FFh
F8h
DAC2 OFFSET
LUT
FFh
Figure 18. Memory Map
______________________________________________________________________________________
27
DS1873
The DS1873 incorporates shadowed-EEPROM memory
locations for key memory addresses that can be written
many times. By default the shadowed-EEPROM bit,
SEEB, is not set and these locations act as ordinary EEPROM. By setting SEEB, these locations function like
SRAM cells, which allow an infinite number of write cycles
without concern of wearing out the EEPROM. Setting
SEEB also eliminates the requirement for the EEPROM
write time, t WR. Because changes made with SEEB
enabled do not affect the EEPROM, these changes are
not retained through power cycles. The power-on value is
the last value written with SEEB disabled. This function
can be used to limit the number of EEPROM writes during
calibration or to change the monitor thresholds periodically during normal operation helping to reduce the number
of times EEPROM is written. Figure 18 indicates which
locations are shadowed EEPROM.
Table 08h contains a temperature-indexed LUT for
control of DAC2. The LUT has 36 entries that determine
the DAC setting in 4°C windows between -40°C and
+100°C.
Auxiliary Memory (device A0h) contains 256 bytes of
EE memory accessible from address 00h–FFh. It is
selected with the device address of A0h.
See the Register Descriptions section for more complete details of each byte’s function, as well as for
read/write permissions for each byte.
DS1873
SFP+ Controller with Analog LDD Interface
Register Descriptions
The register maps show each byte/word (2 bytes) in terms of its row in the memory. The first byte in the row is located in memory at the row address (hexadecimal) in the leftmost column. Each subsequent byte on the row is one/two
memory locations beyond the previous byte/word’s address. A total of 8 bytes are present on each row. For more
information about each of these bytes see the corresponding register description.
Lower Memory Register Map
LOWER MEMORY
WORD 0
WORD 1
WORD 2
WORD 3
ROW
(hex)
ROW NAME
00
<1>THRESHOLD0
08
<1>THRESHOLD1
VCC ALARM HI
VCC ALARM LO
VCC WARN HI
VCC WARN LO
10
<1>THRESHOLD2
MON1 ALARM HI
MON1 ALARM LO
MON1 WARN HI
MON1 WARN LO
18
<1>THRESHOLD3
MON2 ALARM HI
MON2 ALARM LO
MON2 WARN HI
MON2 WARN LO
20
<1>THRESHOLD4
MON3 ALARM HI
MON3 ALARM LO
MON3 WARN HI
MON3 WARN LO
28
<1>THRESHOLD5
MON4 ALARM HI
MON4 ALARM LO
MON4 WARN HI
MON4 WARN LO
30–5F
<1>EEPROM
BYTE 0/8
TEMP ALARM HI
EE
<2>ADC
60
<0>ADC
VALUES1
<2>ALARM/
70
WARN
BYTE 3/B
TEMP ALARM LO
EE
BYTE 4/C
BYTE 5/D
BYTE 6/E
TEMP WARN HI
EE
EE
BYTE 7/F
TEMP WARN LO
EE
EE
EE
VCC VALUE
MON1 VALUE
MON2 VALUE
<2>MON3 VALUE
<2>MON4 VALUE
<2>RESERVED
<0>STATUS <5>UPDATE
ALARM2
ALARM3
<0>TABLE
78
EE
BYTE 2/A
TEMP VALUE
VALUES0
68
BYTE 1/9
ALARM0
<5>
<5>RESERVED
SELECT
ALARM1
WARN3
<6>PWE MSW
RESERVED
WARN2
RESERVED
<5>TBL
<6>PWE LSW
SEL
The access codes represent the factory default values of PW_ENA and PW_ENB (Table 02h, Registers C0h–C1h).
These registers also allow for custom permissions.
ACCESS
CODE
Read
Access
Write
Access
28
<0>
See each
bit/byte
separately
<1>
<2>
<3>
<4>
<5>
<6>
<7>
<8>
<9>
<10>
<11>
All
All
All
PW2
All
N/A
PW1
PW2
N/A
PW2
All
PW2
N/A
All and
DS1873
hardware
PW2 +
mode
bit
All
All
PW1
PW2
PW2
N/A
PW1
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
TABLE 01h
WORD 0
WORD 1
WORD 2
WORD 3
ROW
(hex)
ROW
NAME
BYTE 0/8
BYTE 1/9
BYTE 2/A
BYTE 3/B
BYTE 4/C
BYTE 5/D
BYTE 6/E
BYTE 7/F
80–BF
<7>EEPROM
EE
EE
EE
EE
EE
EE
EE
EE
C0–F7
<8>EEPROM
EE
EE
EE
EE
EE
EE
EE
EE
<8>ALARM
ALARM
EN3
ALARM
EN2
ALARM
EN1
ALARM
EN0
WARN EN3
WARN EN2
RESERVED
RESERVED
F8
ENABLE
The ALARM ENABLE bytes (Registers F8h–FFh) can be configured to exist in Table 05h instead of here at Table 01h
with the MASK bit (Table 02h, Register 89h). If the row is configured to exist in Table 05h, then these locations are
empty in Table 01h.
The access codes represent the factory default values of PW_ENA and PW_ENB (Table 02h, Registers C0h–C1h).
These registers also allow for custom permissions.
ACCESS
CODE
Read
Access
Write
Access
<0>
See each
bit/byte
separately
<1>
<2>
<3>
<4>
<5>
<6>
<7>
<8>
<9>
<10>
<11>
All
All
All
PW2
All
N/A
PW1
PW2
N/A
PW2
All
PW2
N/A
All and
DS1873
hardware
PW2 +
mode
bit
All
All
PW1
PW2
PW2
N/A
PW1
______________________________________________________________________________________
29
DS1873
Table 01h Register Map
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h Register Map
TABLE 02h
WORD 0
WORD 1
WORD 2
WORD 3
ROW
(hex)
ROW
NAME
BYTE 0/8
BYTE 1/9
80
<0>CONFIG0
<8>MODE
<4>TINDEX
88
<8>CONFIG1
UPDATE
RATE
CNFGA
90
<8>SCALE0
XOVER COARSE
VCC SCALE
MON1 SCALE
98
<8>SCALE1
MON3 FINE SCALE
MON4 SCALE
MON3 COARSE SCALE
RESERVED
A0
<8>OFFSET0
XOVER FINE
VCC OFFSET
MON1 OFFSET
MON2 OFFSET
A8
<8>OFFSET1
MON3 FINE OFFSET
MON4 OFFSET
MON3 COARSE OFFSET
INTERNAL TEMP
OFFSET*
B0
<9>PWD VALUE
PW1 MSW
PW1 LSW
PW2 MSW
PW2 LSW
B8
<8>THRESHOLD
LOS
RANGING
COMP
RANGING
IBIASMAX
ISTEP
HTXP
LTXP
HLOS
LLOS
C0
<8>PWD
ENABLE
PW_ENA
PW_ENB
RESERVED
RESERVED
RESERVED
RESERVED
POLARITY
TBLSELPON
C8
<0>BIAS
D0
<8>APC
D8–E7
EMPTY
BYTE 2/A
BYTE 3/B
CNFGB
<4>HBIAS
DAC
DAC
EMPTY
EMPTY
DEVICE
ADDRESS
<10>BIAS DAC
CNTL
<4>APC
BYTE 5/D
BYTE 6/E
<4>DAC1 VALUE
CNFGC
<4>MAN_
<4>MAN BIAS
BYTE 4/C
<4>MOD DAC
RSHIFT2
RESERVED
BYTE 7/F
<4>DAC2 VALUE
RSHIFT1
RSHIFT0
MON2 SCALE
<10>DEVICE <10>DEVICE
ID
VER
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
*The final result must be XORed with BB40h before writing to this register.
The access codes represent the factory default values of PW_ENA and PW_ENB (Table 02h, Registers C0h–C1h).
These registers also allow for custom permissions.
ACCESS
CODE
Read
Access
Write
Access
30
<0>
See each
bit/byte
separately
<1>
<2>
<3>
<4>
<5>
<6>
<7>
<8>
<9>
<10>
<11>
All
All
All
PW2
All
N/A
PW1
PW2
N/A
PW2
All
PW2
N/A
All and
DS1873
hardware
PW2 +
mode
bit
All
All
PW1
PW2
PW2
N/A
PW1
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
TABLE 04h (MODULATION LUT)
WORD 0
WORD 1
WORD 2
WORD 3
ROW
(hex)
ROW
NAME
BYTE 0/8
BYTE 1/9
BYTE 2/A
BYTE 3/B
BYTE 4/C
BYTE 5/D
BYTE 6/E
BYTE 7/F
80
<8>LUT4
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
88
<8>LUT4
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
90
<8>LUT4
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
98
<8>LUT4
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
A0
<8>LUT4
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
A8
<8>LUT4
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
B0
<8>LUT4
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
B8
<8>LUT4
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
C0
<8>LUT4
MOD
MOD
MOD
MOD
MOD
MOD
MOD
MOD
C8–F7
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
MOD OFF
MOD OFF
MOD OFF
MOD OFF
MOD OFF
MOD OFF
MOD OFF
MOD OFF
<8>MOD
F8
OFFSET
Table 05h Register Map
TABLE 05h
WORD 0
WORD 1
WORD 2
WORD 3
ROW
(hex)
ROW
NAME
BYTE 0/8
BYTE 1/9
BYTE 2/A
BYTE 3/B
BYTE 4/C
BYTE 5/D
BYTE 6/E
BYTE 7/F
80–F7
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
<8>ALARM
ALARM
EN3
ALARM
EN2
ALARM
EN1
ALARM
EN0
WARN EN3
WARN EN2
RESERVED
RESERVED
F8
ENABLE
Table 05h is empty by default. It can be configured to contain the alarm and warning-enable bytes from Table 01h,
Registers F8h–FFh with the MASK bit enabled (Table 02h, Register 89h). In this case Table 01h is empty.
The access codes represent the factory default values of PW_ENA and PW_ENB (Table 02h, Registers C0h–C1h).
These registers also allow for custom permissions.
ACCESS
CODE
Read
Access
Write
Access
<0>
See each
bit/byte
separately
<1>
<2>
<3>
<4>
<5>
<6>
<7>
<8>
<9>
<10>
<11>
All
All
All
PW2
All
N/A
PW1
PW2
N/A
PW2
All
PW2
N/A
All and
DS1873
hardware
PW2 +
mode
bit
All
All
PW1
PW2
PW2
N/A
PW1
______________________________________________________________________________________
31
DS1873
Table 04h Register Map
DS1873
SFP+ Controller with Analog LDD Interface
Table 06h Register Map
TABLE 06h (APC LUT)
WORD 0
WORD 1
WORD 2
WORD 3
ROW
(hex)
ROW
NAME
BYTE 0/8
BYTE 1/9
BYTE 2/A
BYTE 3/B
BYTE 4/C
BYTE 5/D
BYTE 6/E
BYTE 7/F
80–9F
<8>LUT6
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
88
<8>LUT6
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
90
<8>LUT6
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
98
<8>LUT6
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
APC REF
A0
<8>LUT6
APC REF
APC REF
APC REF
APC REF
RESERVED
RESERVED
RESERVED
RESERVED
A8–F7
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
F8
<8>HBATH
HBIAS
HBIAS
HBIAS
HBIAS
HBIAS
HBIAS
HBIAS
HBIAS
Table 07h Register Map
TABLE 07h (DAC1 LUT)
WORD 0
WORD 1
WORD 2
WORD 3
ROW
(hex)
ROW
NAME
BYTE 0/8
BYTE 1/9
BYTE 2/A
BYTE 3/B
BYTE 4/C
BYTE 5/D
BYTE 6/E
BYTE 7/F
80
<8>LUT7
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
88
<8>LUT7
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
90
<8>LUT7
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
98
<8>LUT7
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
A0
<8>LUT7
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
A8
<8>LUT7
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
B0
<8>LUT7
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
B8
<8>LUT7
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
C0
<8>LUT7
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
DAC1
C8–F7
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
DAC1 OFF
DAC1 OFF
DAC1 OFF
DAC1 OFF
DAC1 OFF
DAC1 OFF
DAC1 OFF
DAC1 OFF
<8>DAC1
F8
OFFSET
The access codes represent the factory default values of PW_ENA and PW_ENB (Table 02h, Registers C0h–C1h).
These registers also allow for custom permissions.
ACCESS
CODE
Read
Access
Write
Access
32
<0>
See each
bit/byte
separately
<1>
<2>
<3>
<4>
<5>
<6>
<7>
<8>
<9>
<10>
<11>
All
All
All
PW2
All
N/A
PW1
PW2
N/A
PW2
All
PW2
N/A
All and
DS1873
hardware
PW2 +
mode
bit
All
All
PW1
PW2
PW2
N/A
PW1
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
TABLE 08h (DAC2 LUT)
WORD 0
WORD 1
WORD 2
WORD 3
ROW
(hex)
ROW
NAME
BYTE 0/8
BYTE 1/9
BYTE 2/A
BYTE 3/B
BYTE 4/C
BYTE 5/D
BYTE 6/E
BYTE 7/F
80
<8>LUT8
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
88
<8>LUT8
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
90
<8>LUT8
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
98
<8>LUT8
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
DAC2
A0
<8>LUT8
DAC2
DAC2
DAC2
DAC2
RESERVED
RESERVED
RESERVED
RESERVED
C8–F7
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
EMPTY
DAC2 OFF
DAC2 OFF
DAC2 OFF
DAC2 OFF
DAC2 OFF
DAC2 OFF
DAC2 OFF
DAC2 OFF
<8>DAC2
F8
OFFSET
Auxiliary A0h Memory Register Map
AUXILIARY MEMORY (A0h)
WORD 0
ROW
(hex)
ROW
NAME
00–7F
80–FF
<5>AUX EE
<5>AUX EE
WORD 1
WORD 2
WORD 3
BYTE 0/8
BYTE 1/9
BYTE 2/A
BYTE 3/B
BYTE 4/C
BYTE 5/D
BYTE 6/E
BYTE 7/F
EE
EE
EE
EE
EE
EE
EE
EE
EE
EE
EE
EE
EE
EE
EE
EE
The access codes represent the factory default values of PW_ENA and PW_ENB (Table 02h, Registers C0h–C1h).
These registers also allow for custom permissions.
ACCESS
CODE
Read
Access
Write
Access
<0>
See each
bit/byte
separately
<1>
<2>
<3>
<4>
<5>
<6>
<7>
<8>
<9>
<10>
<11>
All
All
All
PW2
All
N/A
PW1
PW2
N/A
PW2
All
PW2
N/A
All and
DS1873
hardware
PW2 +
mode
bit
All
All
PW1
PW2
PW2
N/A
PW1
______________________________________________________________________________________
33
DS1873
Table 08h Register Map
DS1873
SFP+ Controller with Analog LDD Interface
Lower Memory Register Descriptions
Lower Memory, Register 00h–01h: TEMP ALARM HI
Lower Memory, Register 04h–05h: TEMP WARN HI
FACTORY DEFAULT
7FFFh
READ ACCESS
All
WRITE ACCESS
PW2 or (PW1 and WLOWER)
MEMORY TYPE
Nonvolatile (SEE)
00h, 04h
S
26
25
24
23
22
21
20
01h, 05h
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
BIT 7
BIT 0
Temperature measurement updates above this two’s complement threshold set corresponding alarm or warning bits.
Temperature measurement updates equal to or below this threshold clear alarm or warning bits.
Lower Memory, Register 02h–03h: TEMP ALARM LO
Lower Memory, Register 06h–07h: TEMP WARN LO
FACTORY DEFAULT
8000h
READ ACCESS
All
WRITE ACCESS
PW2 or (PW1 and WLOWER)
MEMORY TYPE
Nonvolatile (SEE)
02h, 06h
S
26
25
24
23
22
21
20
03h, 07h
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
BIT 7
BIT 0
Temperature measurement updates below this two’s complement threshold set corresponding alarm or warning bits.
Temperature measurement updates equal to or above this threshold clear alarm or warning bits.
34
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
08h, 0Ch, 10h,
14h, 18h, 1Ch,
20h, 24h, 28h,
2Ch
09h, 0Dh, 11h,
15h, 19h, 1Dh,
21h, 25h, 29h,
2Dh
DS1873
Lower Memory, Register 08h–09h: VCC ALARM HI
Lower Memory, Register 0Ch–0Dh: VCC WARN HI
Lower Memory, Register 10h–11h: MON1 ALARM HI
Lower Memory, Register 14h–15h: MON1 WARN HI
Lower Memory, Register 18h–19h: MON2 ALARM HI
Lower Memory, Register 1Ch–1Dh: MON2 WARN HI
Lower Memory, Register 20h–21h: MON3 ALARM HI
Lower Memory, Register 24h–25h: MON3 WARN HI
Lower Memory, Register 28h–29h: MON4 ALARM HI
Lower Memory, Register 2Ch–2Dh: MON4 WARN HI
FACTORY DEFAULT
FFFFh
READ ACCESS
All
WRITE ACCESS
PW2 or (PW1 and WLOWER)
MEMORY TYPE
Nonvolatile (SEE)
215
214
213
212
211
210
29
28
27
26
25
24
23
22
21
20
BIT 7
BIT 0
Voltage measurement updates above this unsigned threshold set corresponding alarm or warning bits. Voltage
measurements equal to or below this threshold clear alarm or warning bits.
______________________________________________________________________________________
35
DS1873
SFP+ Controller with Analog LDD Interface
Lower Memory, Register 0Ah–0Bh: VCC ALARM LO
Lower Memory, Register 0Eh–0Fh: VCC WARN LO
Lower Memory, Register 12h–13h: MON1 ALARM LO
Lower Memory, Register 16h–17h: MON1 WARN LO
Lower Memory, Register 1Ah–1Bh: MON2 ALARM LO
Lower Memory, Register 1Eh–1Fh: MON2 WARN LO
Lower Memory, Register 22h–23h: MON3 ALARM LO
Lower Memory, Register 26h–27h: MON3 WARN LO
Lower Memory, Register 2Ah–2Bh: MON4 ALARM LO
Lower Memory, Register 2Eh–2Fh: MON4 WARN LO
0Ah, 0Eh,
12h, 16h,
1Ah, 1Eh,
22h, 26h,
2Ah, 2Eh
0Bh, 0Fh,
13h, 17h,
1Bh, 1Fh,
23h, 27h,
2Bh, 2Fh
FACTORY DEFAULT
0000h
READ ACCESS
All
WRITE ACCESS
PW2 or (PW1 and WLOWER)
MEMORY TYPE
Nonvolatile (SEE)
215
214
213
212
211
210
29
28
27
26
25
24
23
22
21
20
BIT 7
BIT 0
Voltage measurement updates below this unsigned threshold set corresponding alarm or warning bits. Voltage
measurements equal to or above this threshold clear alarm or warning bits.
36
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
30h–5Fh
FACTORY DEFAULT
00h
READ ACCESS
All
WRITE ACCESS
PW2 or (PW1 and WLOWER)
MEMORY TYPE
Nonvolatile (EE)
EE
EE
EE
EE
DS1873
Lower Memory, Register 30h–5Fh: EE
EE
EE
EE
BIT 7
EE
BIT 0
PW2 level access-controlled EEPROM.
Lower Memory, Register 60h–61h: TEMP VALUE
FACTORY DEFAULT
0000h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
Volatile
60h
S
26
25
24
23
22
21
20
61h
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
BIT 7
BIT 0
Signed two’s complement direct-to-temperature measurement.
______________________________________________________________________________________
37
DS1873
SFP+ Controller with Analog LDD Interface
Lower Memory, Register 62h–63h: VCC VALUE
Lower Memory, Register 64h–65h: MON1 VALUE
Lower Memory, Register 66h–67h: MON2 VALUE
Lower Memory, Register 68h–69h: MON3 VALUE
Lower Memory, Register 6Ah–6Bh: MON4 VALUE
62h, 64h,
66h, 68h,
6Ah
63h, 65h,
67h, 69h,
6Bh
POWER-ON VALUE
0000h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
Volatile
215
214
213
212
211
210
29
28
27
26
25
24
23
22
21
20
BIT 7
BIT 0
Left-justified unsigned voltage measurement.
Lower Memory, Register 6Ch–6Dh: RESERVED
POWER-ON VALUE
00h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
6Ch, 6Dh
0
0
0
0
0
0
0
BIT 7
These registers are reserved. The value when read is 00h.
38
______________________________________________________________________________________
0
BIT 0
SFP+ Controller with Analog LDD Interface
DS1873
Lower Memory, Register 6Eh: STATUS
POWER-ON VALUE
Write Access
6Eh
X0XX 0XXXb
READ ACCESS
All
WRITE ACCESS
See below
MEMORY TYPE
Volatile
N/A
All
N/A
All
All
N/A
N/A
N/A
TXDS
TXDC
IN1S
RSELS
RSELC
TXFS
RXL
RDYB
BIT 7
BIT 0
BIT 7
TXDS: TXD Status Bit. Reflects the logic state of the TXD pin (read only).
0 = TXD pin is logic-low.
1 = TXD pin is logic-high.
BIT 6
TXDC: TXD Software Control Bit. This bit allows for software control that is identical to the TXD pin.
See the section on TXD for further information. Its value is wire-ORed with the logic value of the
TXD pin (writable by all users).
0 = (Default).
1 = Forces the device into a TXD state regardless of the value of the TXD pin.
BIT 5
IN1S: IN1 Status Bit. Reflects the logic state of the IN1 pin (read only).
0 = IN1 pin is logic-low.
1 = IN1 pin is logic-high.
BIT 4
RSELS: RSEL Status Bit. Reflects the logic state of the RSEL pin (read only).
0 = RSEL pin is logic-low.
1 = RSEL pin is logic-high.
BIT 3
RSELC: RSEL Software Control Bit. This bit allows for software control that is identical to the RSEL
pin. Its value is wire-ORed with the logic value of the RSEL pin to create the RSELOUT pin’s logic
value (writable by all users).
0 = (Default).
1 = Forces the device into a RSEL state regardless of the value of the RSEL pin.
BIT 2
TXFS: Reflects the driven state of the TXF pin (read only).
0 = TXF pin is low.
1 = TXF pin is high.
BIT 1
RXL: Reflects the driven state of the LOSOUT pin (read only).
0 = LOSOUT pin is driven low.
1 = LOSOUT pin is pulled high.
BIT 0
RDYB: Ready Bar.
0 = VCC is above POA.
1 = VCC is below POA and/or too low to communicate over the I2C bus.
______________________________________________________________________________________
39
DS1873
SFP+ Controller with Analog LDD Interface
Lower Memory, Register 6Fh: UPDATE
6Fh
POWER-ON VALUE
00h
READ ACCESS
All
WRITE ACCESS
All and DS1873 Hardware
MEMORY TYPE
Volatile
TEMP RDY
VCC RDY
MON1 RDY
MON2 RDY
MON3 RDY
MON4 RDY
RESERVED
BIT 7
BITS 7:2
40
RSSIR
BIT 0
Update of completed conversions. At power-on, these bits are cleared and are set as each conversion is
completed. These bits can be cleared so that a completion of a new conversion is verified.
BIT 1
RESERVED
BIT 0
RSSIR: RSSI Range. Reports the range used for conversion update of MON3.
0 = Fine range is the reported value.
1 = Coarse range is the reported value.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
DS1873
Lower Memory, Register 70h: ALARM3
70h
POWER-ON VALUE
10h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
Volatile
TEMP HI
TEMP LO
VCC HI
VCC LO
MON1 HI
MON1 LO
BIT 7
MON2 HI
MON2 LO
BIT 0
BIT 7
TEMP HI: High-alarm status for temperature measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 6
TEMP LO: Low-alarm status for temperature measurement.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
BIT 5
VCC HI: High-alarm status for VCC measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 4
VCC LO: Low-alarm status for VCC measurement. This bit is set when the VCC supply is below the POA trip
point value. It clears itself when a VCC measurement is completed and the value is above the low threshold.
0 = Last measurement was equal to or above threshold setting.
1 = (Default) Last measurement was below threshold setting.
BIT 3
MON1 HI: High-alarm status for MON1 measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 2
MON1 LO: Low-alarm status for MON1 measurement.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
BIT 1
MON2 HI: High-alarm status for MON2 measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 0
MON2 LO: Low-alarm status for MON2 measurement.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
______________________________________________________________________________________
41
DS1873
SFP+ Controller with Analog LDD Interface
Lower Memory, Register 71h: ALARM2
71h
POWER-ON VALUE
00h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
Volatile
MON3 HI
MON3 LO
MON4 HI
MON4 LO
RESERVED
RESERVED
RESERVED
BIT 7
MON3 HI: High-alarm status for MON3 measurement. A TXD event does not clear this alarm.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 6
MON3 LO: Low-alarm status for MON3 measurement. A TXD event does not clear this alarm.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
BIT 5
MON4 HI: High-alarm status for MON4 measurement. A TXD event does not clear this alarm.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 4
MON4 LO: Low-alarm status for MON4 measurement. A TXD event does not clear this alarm.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
BIT 0
42
BIT 0
BIT 7
BITS 3:1
TXFINT
RESERVED
TXFINT: TXF Interrupt. This bit is the wire-ORed logic of all alarms and warnings wire-ANDed with their
corresponding enable bits in addition to nonmaskable alarms TXP HI, TXP LO, BIAS MAX, and HBAL. The
enable bits are found in Table 01h/05h, Registers F8h–FFh.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
72h
POWER-ON VALUE
00h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
Volatile
RESERVED
RESERVED
RESERVED
DS1873
Lower Memory, Register 72h: ALARM1
RESERVED
HBAL
RESERVED
TXP HI
TXP LO
BIT 7
BIT 0
BITS 7:4
RESERVED
BIT 3
HBAL: High-Bias Alarm Status; Fast Comparison. A TXD event clears this alarm.
0 = (Default) Last comparison was below threshold setting.
1 = Last comparison was above threshold setting.
BIT 2
RESERVED
BIT 1
TXP HI: High-Alarm Status TXP; Fast Comparison. A TXD event clears this alarm.
0 = (Default) Last comparison was below threshold setting.
1 = Last comparison was above threshold setting.
BIT 0
TXP LO: Low-Alarm Status TXP; Fast Comparison. A TXD event clears this alarm.
0 = (Default) Last comparison was above threshold setting.
1 = Last comparison was below threshold setting.
Lower Memory, Register 73h: ALARM0
73h
POWER-ON VALUE
00h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
Volatile
LOS HI
LOS LO
RESERVED
RESERVED
BIAS MAX
RESERVED
RESERVED
RESERVED
BIT 7
BIT 0
BIT 7
LOS HI: High-Alarm Status for MON3; Fast Comparison. A TXD event does not clear this alarm.
0 = (Default) Last comparison was below threshold setting.
1 = Last comparison was above threshold setting.
BIT 6
LOS LO: Low-Alarm Status for MON3; Fast Comparison. A TXD event does not clear this alarm.
0 = (Default) Last comparison was above threshold setting.
1 = Last comparison was below threshold setting.
BITS 5:4
BIT 3
BITS 2:0
RESERVED
BIAS MAX: Alarm status for maximum digital setting of BIAS. A TXD event clears this alarm.
0 = (Default) The value for BIAS is equal to or below the IBIASMAX register.
1 = Requested value for BIAS is greater than the IBIASMAX register.
RESERVED
______________________________________________________________________________________
43
DS1873
SFP+ Controller with Analog LDD Interface
Lower Memory, Register 74h: WARN3
74h
POWER-ON VALUE
10h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
Volatile
TEMP HI
TEMP LO
VCC HI
VCC LO
MON1 HI
MON1 LO
MON2 HI
BIT 7
44
MON2 LO
BIT 0
BIT 7
TEMP HI: High-warning status for temperature measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 6
TEMP LO: Low-warning status for temperature measurement.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
BIT 5
VCC HI: High-warning status for VCC measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 4
VCC LO: Low-warning status for VCC measurement. This bit is set when the VCC supply is below the POA
trip point value. It clears itself when a VCC measurement is completed and the value is above the low
threshold.
0 = Last measurement was equal to or above threshold setting.
1 = (Default) Last measurement was below threshold setting.
BIT 3
MON1 HI: High-warning status for MON1 measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 2
MON1 LO: Low-warning status for MON1 measurement.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
BIT 1
MON2 HI: High-warning status for MON2 measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 0
MON2 LO: Low-warning status for MON2 measurement.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
75h
POWER-ON VALUE
00h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
Volatile
MON3 HI
MON3 LO
MON4 HI
DS1873
Lower Memory, Register 75h: WARN2
MON4 LO
RESERVED
RESERVED
BIT 7
RESERVED
RESERVED
BIT 0
BIT 7
MON3 HI: High-warning status for MON3 measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 6
MON3 LO: Low-warning status for MON3 measurement.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
BIT 5
MON4 HI: High-warning status for MON4 measurement.
0 = (Default) Last measurement was equal to or below threshold setting.
1 = Last measurement was above threshold setting.
BIT 4
MON4 LO: Low-warning status for MON4 measurement.
0 = (Default) Last measurement was equal to or above threshold setting.
1 = Last measurement was below threshold setting.
BITS 3:0
RESERVED
Lower Memory, Register 76h–7Ah: RESERVED MEMORY
POWER-ON VALUE
00h
READ ACCESS
All
WRITE ACCESS
N/A
MEMORY TYPE
These registers are reserved. The value when read is 00h.
______________________________________________________________________________________
45
DS1873
SFP+ Controller with Analog LDD Interface
Lower Memory, Register 7Bh–7Eh: Password Entry (PWE)
POWER-ON VALUE
FFFF FFFFh
READ ACCESS
N/A
WRITE ACCESS
All
MEMORY TYPE
Volatile
7Bh
231
230
229
228
227
226
225
224
7Ch
223
222
221
220
219
218
217
216
7Dh
215
214
213
212
211
210
29
28
7Eh
27
26
25
24
23
22
21
20
BIT 7
BIT 0
There are two passwords for the DS1873. Each password is 4 bytes long. The lower level password (PW1) has all the
access of a normal user plus those made available with PW1. The higher level password (PW2) has all the access of
PW1 plus those made available with PW2. The values of the passwords reside in EEPROM inside PW2 memory. At
power-up, all PWE bits are set to 1. All reads at this location are 0.
Lower Memory, Register 7Fh: Table Select (TBL SEL)
7Fh
POWER-ON VALUE
TBLSELPON (Table 02h, Register C7h)
READ ACCESS
All
WRITE ACCESS
All
MEMORY TYPE
Volatile
27
26
25
24
23
22
21
BIT 7
20
BIT 0
The upper memory tables of the DS1873 are accessible by writing the desired table value in this register. The power-on
value of this register is defined by the value written to TBLSELPON (Table 02h, Register C7h).
46
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
Table 01h, Register 80h–BFh: EEPROM
80h–BFh
POWER-ON VALUE
00h
READ ACCESS
PW2 or (PW1 and RWTBL1A) or (PW1 and RTBL1A)
WRITE ACCESS
PW2 or (PW1 and RWTBL1A)
MEMORY TYPE
Nonvolatile (EE)
EE
EE
EE
EE
EE
EE
EE
BIT 7
EE
BIT 0
EEPROM for PW1 and/or PW2 level access.
Table 01h, Register C0h–F7h: EEPROM
C0h–F7h
POWER-ON VALUE
00h
READ ACCESS
PW2 or (PW1 and RWTBL1B) or (PW1 and RTBL1B)
WRITE ACCESS
PW2 or (PW1 and RWTBL1B)
MEMORY TYPE
Nonvolatile (EE)
EE
EE
EE
BIT 7
EE
EE
EE
EE
EE
BIT 0
EEPROM for PW1 and/or PW2 level access.
______________________________________________________________________________________
47
DS1873
Table 01h Register Descriptions
DS1873
SFP+ Controller with Analog LDD Interface
Table 01h, Register F8h: ALARM EN3
F8h
POWER-ON VALUE
00h
READ ACCESS
PW2 or (PW1 and RWTBL1C) or (PW1 and RTBL1C)
WRITE ACCESS
PW2 or (PW1 and RWTBL1C)
MEMORY TYPE
Nonvolatile (SEE)
TEMP HI
TEMP LO
VCC HI
VCC LO
MON1 HI
MON1 LO
MON2 HI
BIT 7
MON2 LO
BIT 0
Layout is identical to ALARM3 in Lower Memory, Register 70h. Enables alarms to create TXFINT (Lower Memory,
Register 71h) logic. The MASK bit (Table 02h, Register 89h) determines whether this memory exists in Table 01h
or 05h.
48
BIT 7
TEMP HI:
0 = Disables interrupt from TEMP HI alarm.
1 = Enables interrupt from TEMP HI alarm.
BIT 6
TEMP LO:
0 = Disables interrupt from TEMP LO alarm.
1 = Enables interrupt from TEMP LO alarm.
BIT 5
VCC HI:
0 = Disables interrupt from VCC HI alarm.
1 = Enables interrupt from VCC HI alarm.
BIT 4
VCC LO:
0 = Disables interrupt from VCC LO alarm.
1 = Enables interrupt from VCC LO alarm.
BIT 3
MON1 HI:
0 = Disables interrupt from MON1 HI alarm.
1 = Enables interrupt from MON1 HI alarm.
BIT 2
MON1 LO:
0 = Disables interrupt from MON1 LO alarm.
1 = Enables interrupt from MON1 LO alarm.
BIT 1
MON2 HI:
0 = Disables interrupt from MON2 HI alarm.
1 = Enables interrupt from MON2 HI alarm.
BIT 0
MON2 LO:
0 = Disables interrupt from MON2 LO alarm.
1 = Enables interrupt from MON2 LO alarm.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
F9h
POWER-ON VALUE
00h
READ ACCESS
PW2 or (PW1 and RWTBL1C) or (PW1 and RTBL1C)
WRITE ACCESS
PW2 or (PW1 and RWTBL1C)
MEMORY TYPE
Nonvolatile (SEE)
MON3 HI
MON3 LO
MON4 HI
MON4 LO
BIT 7
RESERVED
RESERVED
DS1873
Table 01h, Register F9h: ALARM EN2
RESERVED
RESERVED
BIT 0
Layout is identical to ALARM2 in Lower Memory, Register 71h. Enables alarms to create TXFINT (Lower Memory,
Register 71h) logic. The MASK bit (Table 02h, Register 89h) determines whether this memory exists in Table 01h or
05h.
BIT 7
MON3 HI:
0 = Disables interrupt from MON3 HI alarm.
1 = Enables interrupt from MON3 HI alarm.
BIT 6
MON3 LO:
0 = Disables interrupt from MON3 LO alarm.
1 = Enables interrupt from MON3 LO alarm.
BIT 5
MON4 HI:
0 = Disables interrupt from MON4 HI alarm.
1 = Enables interrupt from MON4 HI alarm.
BIT 4
MON4 LO:
0 = Disables interrupt from MON4 LO alarm.
1 = Enables interrupt from MON4 LO alarm.
BIT 3:0
RESERVED
______________________________________________________________________________________
49
DS1873
SFP+ Controller with Analog LDD Interface
Table 01h, Register FAh: ALARM EN1
FAh
POWER-ON VALUE
00h
READ ACCESS
PW2 or (PW1 and RWTBL1C) or (PW1 and RTBL1C)
WRITE ACCESS
PW2 or (PW1 and RWTBL1C)
MEMORY TYPE
Nonvolatile (SEE)
RESERVED
RESERVED
RESERVED
RESERVED
HBAL
RESERVED
TXP HI
BIT 7
TXP LO
BIT 0
Layout is identical to ALARM1 in Lower Memory, Register 72h. Enables alarms to create internal signal FETG (see
Figure 12) logic. The MASK bit (Table 02h, Register 89h) determines whether this memory exists in Table 01h or
05h.
BITS 7:4
50
RESERVED
BIT 3
HBAL:
0 = Disables interrupt from HBAL alarm.
1 = Enables interrupt from HBAL alarm.
BIT 2
RESERVED
BIT 1
TXP HI:
0 = Disables interrupt from TXP HI alarm.
1 = Enables interrupt from TXP HI alarm.
BIT 0
TXP LO:
0 = Disables interrupt from TXP LO alarm.
1 = Enables interrupt from TXP LO alarm.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
FBh
POWER-ON VALUE
00h
READ ACCESS
PW2 or (PW1 and RWTBL1C) or (PW1 and RTBL1C)
WRITE ACCESS
PW2 or (PW1 and RWTBL1C)
MEMORY TYPE
Nonvolatile (SEE)
LOS HI
LOS LO
RESERVED
RESERVED
BIAS MAX
RESERVED
DS1873
Table 01h, Register FBh: ALARM EN0
RESERVED
BIT 7
RESERVED
BIT 0
Layout is identical to ALARM1 in Lower Memory, Register 73h. The MASK bit (Table 02h, Register 89h) determines
whether this memory exists in Table 01h or 05h.
BIT 7
LOS HI: Enables alarm to create TXFINT (Lower Memory, Register 71h) logic.
0 = Disables interrupt from LOS HI alarm.
1 = Enables interrupt from LOS HI alarm.
BIT 6
LOS LO: Enables alarm to create TXFINT (Lower Memory, Register 71h) logic.
0 = Disables interrupt from LOS LO alarm.
1 = Enables interrupt from LOS LO alarm.
BITS 5:4
BIT 3
BITS 2:0
RESERVED
BIAS MAX: Enables alarm to create internal signal FETG (see Figure 12) logic.
0 = Disables interrupt from BIAS MAX alarm.
1 = Enables interrupt from BIAS MAX alarm.
RESERVED
______________________________________________________________________________________
51
DS1873
SFP+ Controller with Analog LDD Interface
Table 01h, Register FCh: WARN EN3
FCh
POWER-ON VALUE
00h
READ ACCESS
PW2 or (PW1 and RWTBL1C) or (PW1 and RTBL1C)
WRITE ACCESS
PW2 or (PW1 and RWTBL1C)
MEMORY TYPE
Nonvolatile (SEE)
TEMP HI
TEMP LO
VCC HI
VCC LO
MON1 HI
MON1 LO
MON2 HI
BIT 7
MON2 LO
BIT 0
Layout is identical to WARN3 in Lower Memory, Register 74h. Enables warnings to create TXFINT (Lower Memory,
Register 71h) logic. The MASK bit (Table 02h, Register 89h) determines whether this memory exists in Table 01h
or 05h.
52
BIT 7
TEMP HI:
0 = Disables interrupt from TEMP HI warning.
1 = Enables interrupt from TEMP HI warning.
BIT 6
TEMP LO:
0 = Disables interrupt from TEMP LO warning.
1 = Enables interrupt from TEMP LO warning.
BIT 5
VCC HI:
0 = Disables interrupt from VCC HI warning.
1 = Enables interrupt from VCC HI warning.
BIT 4
VCC LO:
0 = Disables interrupt from VCC LO warning.
1 = Enables interrupt from VCC LO warning.
BIT 3
MON1 HI:
0 = Disables interrupt from MON1 HI warning.
1 = Enables interrupt from MON1 HI warning.
BIT 2
MON1 LO:
0 = Disables interrupt from MON1 LO warning.
1 = Enables interrupt from MON1 LO warning.
BIT 1
MON2 HI:
0 = Disables interrupt from MON2 HI warning.
1 = Enables interrupt from MON2 HI warning.
BIT 0
MON2 LO:
0 = Disables interrupt from MON2 LO warning.
1 = Enables interrupt from MON2 LO warning.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
FDh
POWER-ON VALUE
00h
READ ACCESS
PW2 or (PW1 and RWTBL1C) or (PW1 and RTBL1C)
WRITE ACCESS
PW2 or (PW1 and RWTBL1C)
MEMORY TYPE
Nonvolatile (SEE)
MON3 HI
MON3 LO
MON4 HI
MON4 LO
RESERVED
RESERVED
BIT 7
DS1873
Table 01h, Register FDh: WARN EN2
RESERVED
RESERVED
BIT 0
Layout is identical to WARN2 in Lower Memory, Register 75h. Enables warnings to create TXFINT (Lower Memory,
Register 71h) logic. The MASK bit (Table 02h, Register 89h) determines whether this memory exists in Table 01h or
05h.
BIT 7
MON3 HI:
0 = Disables interrupt from MON3 HI warning.
1 = Enables interrupt from MON3 HI warning.
BIT 6
MON3 LO:
0 = Disables interrupt from MON3 LO warning.
1 = Enables interrupt from MON3 LO warning.
BIT 5
MON4 HI:
0 = Disables interrupt from MON4 HI warning.
1 = Enables interrupt from MON4 HI warning.
BIT 4
MON4 LO:
0 = Disables interrupt from MON4 LO warning.
1 = Enables interrupt from MON4 LO warning.
BITS 3:0
RESERVED
Table 01h, Register FEh–FFh: RESERVED
POWER-ON VALUE
00h
READ ACCESS
PW2 or (PW1 and RWTBL1C) or (PW1 and RTBL1C)
WRITE ACCESS
PW2 or (PW1 and RWTBL1C)
MEMORY TYPE
Nonvolatile (SEE)
These registers are reserved.
______________________________________________________________________________________
53
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h Register Descriptions
Table 02h, Register 80h: MODE
80h
POWER-ON VALUE
3Fh
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and PRTBL2)
MEMORY TYPE
Volatile
SEEB
RESERVED
DAC1 EN
DAC2 EN
AEN
MOD EN
APC EN
BIT 7
BIT 0
BIT 7
SEEB:
0 = (Default) Enables EEPROM writes to SEE bytes.
1 = Disables EEPROM writes to SEE bytes during configuration, so that the configuration of the part
is not delayed by the EE cycle time. Once the values are known, write this bit to a 0 and write the
SEE locations again for data to be written to the EEPROM.
BIT 6
RESERVED
BIT 5
BIT 4
BIT 3
BIT 2
54
BIAS EN
DAC1 EN:
0 = DAC1 VALUE is writable by the user and the LUT recalls are disabled. This allows users to
interactively test their modules by writing the values for DAC1. The output is updated with the new
value at the end of the write cycle. The I2C STOP condition is the end of the write cycle.
1 = (Default) Enables auto control of the LUT for DAC1 VALUE.
DAC2 EN:
0 = DAC2 VALUE is writable by the user and the LUT recalls are disabled. This allows users to
interactively test their modules by writing the values for DAC2. The output is updated with the new
value at the end of the write cycle. The I2C STOP condition is the end of the write cycle.
1 = (Default) Enables auto control of the LUT for DAC2 VALUE.
AEN:
0 = The temperature-calculated index value TINDEX is writable by users and the updates of
calculated indexes are disabled. This allows users to interactively test their modules by
controlling the indexing for the LUTs. The recalled values from the LUTs appear in the DAC
registers after the next completion of a temperature conversion.
MOD EN:
0 = Modulation is writable by the user and the LUT recalls are disabled. This allows users to
interactively test their modules by writing the DAC value for modulation. The output is updated with the
new value at the end of the write cycle. The I2C STOP condition is the end of the write cycle.
1 = (Default) Enables auto control of the LUT for modulation.
BIT 1
APC EN:
0 = APC DAC is writable by the user and the LUT recalls are disabled. This allows users to
interactively test their modules by writing the DAC value for APC reference. The I2C STOP condition is
the end of the write cycle. The HBIAS DAC is also writable if recalls are disabled.
1 = (Default) Enables auto control of the LUT for APC reference.
BIT 0
BIAS EN:
0 = BIAS DAC is controlled by the user and the APC is in manual mode. This allows the user to
interactively test their modules by writing the DAC value for bias.
1 = (Default) Enables auto control for the APC feedback.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
81h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
(PW2 and AEN = 0) or (PW1 and RWTBL2 and AEN = 0)
MEMORY TYPE
Volatile
27
26
25
24
23
22
DS1873
Table 02h, Register 81h: Temperature Index (TINDEX)
21
BIT 7
20
BIT 0
Holds the calculated index based on the temperature measurement. This index is used for the address during
lookup of Tables 04h, 06h–08h. Temperature measurements below -40°C or above +102°C are clamped to 80h and
C7h, respectively. The calculation of TINDEX is as follows:
TINDEX =
Temp _ Value + 40°C
+ 80h
2°C
For the temperature-indexed LUTs (2°C and 4°C), the index used during the lookup function for each table is as follows:
Table 04h (MOD)
1
TINDEX6
TINDEX5
TINDEX4
TINDEX3
TINDEX2
TINDEX1
TINDEX0
Table 06h (APC)
1
0
TINDEX6
TINDEX5
TINDEX4
TINDEX3
TINDEX2
TINDEX1
Table 07h (DAC1)
1
1
TINDEX6
0
TINDEX5
TINDEX4
TINDEX3
TINDEX2
TINDEX1
TINDEX0
TINDEX6
TINDEX5
TINDEX4
TINDEX3
TINDEX2
TINDEX1
Table 08h (DAC2)
For the 8-position LUT tables, the following table shows the lookup function:
TINDEX
BYTE
TEMP
(°C)
1000_0xxx
F8
1001_0xxx
F9
1001_1xxx
FA
1010_0xxx
FB
1010_1xxx
FC
1011_0xxx
FD
1011_1xxx
FE
11xx_xxxx
FF
< -8
-8 to +8
8 to 24
24 to 40
40 to 56
56 to 72
72 to 88
88
______________________________________________________________________________________
55
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register 82h–83h: MOD DAC
FACTORY DEFAULT
0000h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
(PW2 and MOD EN = 0) or (PW1 and RWTBL2 and MOD EN = 0)
MEMORY TYPE
Volatile
82h
0
0
0
0
0
0
0
28
83h
27
26
25
24
23
22
21
20
BIT 7
BIT 0
The digital value used for MOD DAC. It is the result of LUT4 plus MOD OFFSET times 4 recalled from Table 04h at
the adjusted memory address found in TINDEX. This register is updated at the end of the temperature conversion.
MOD VALUE = LUT4 + MOD OFFSET 4
VMOD =
VREFIN
MOD VALUE
1024
Table 02h, Register 84h–85h: DAC1 VALUE
FACTORY DEFAULT
0000h
READ ACCESS
PW2 or (PW1 and RWTBL246) or (PW1 and RTBL246)
WRITE ACCESS
(PW2 and DAC1 EN = 0) or (PW1 and RWTBL246 and DAC1 EN = 0)
MEMORY TYPE
Volatile
84h
0
0
0
0
0
0
0
28
85h
27
26
25
24
23
22
21
20
BIT 7
BIT 0
The digital value used for DAC1. It is the result of LUT7 plus DAC1 OFFSET times 4 recalled from Table 07h at the
adjusted memory address found in TINDEX. This register is updated at the end of the temperature conversion.
DAC1 VALUE = LUT7 + DAC1 OFFSET 4
VDAC1 =
56
VREFIN
DAC1 VALUE
1024
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
DS1873
Table 02h, Register 86h–87h: DAC2 VALUE
FACTORY DEFAULT
0000h
READ ACCESS
PW2 or (PW1 and RWTBL246) or (PW1 and RTBL246)
WRITE ACCESS
(PW2 and DAC2 EN = 0) or (PW1 and RWTBL246 and DAC2 EN = 0)
MEMORY TYPE
Volatile
86h
0
0
0
0
0
0
0
28
87h
27
26
25
24
23
22
21
20
BIT 7
BIT 0
The digital value used for DAC2. It is the result of LUT8 plus DAC2 OFFSET times 4 recalled from Table 08h at the
adjusted memory address found in TINDEX. This register is updated at the end of the temperature conversion.
DAC2 VALUE = LUT8 + DAC2 OFFSET 4
VDAC2 =
VREFIN
DAC2 VALUE
1024
Table 02h, Register 88h: UPDATE RATE
88h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
SEE
SEE
SEE
SEE
APC_SR3
APC_SR2
BIT 7
APC_SR1
APC_SR0
BIT 0
BITS 7:4
SEE
BITS 3:0
APC_SR[3:0]: 4-bit sample rate for comparison of APC control. Defines the sample rate for comparison of
APC control.
The quick-trip comparator uses a 1.6μs window to sample each input. After an APC comparison that requires an
update to the BIAS DAC, a settling time (as calculated below) is required to allow for the feedback on BMD (MON2)
to stabilize. This time is dependent on the time constant of the filter pole used for the delta-to-sigma BIAS output.
During the timing of the settling rate, comparisons of APC comparisons of BMD are ignored until 32 sample periods
(tREP) have passed.
SettlingTime = 51.2μs x (APC_SR[3:0] + 1)
______________________________________________________________________________________
57
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register 89h: CNFGA
89h
FACTORY DEFAULT
80h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
LOSC
RESERVED
INV LOS
ASEL
MASK
INVRSOUT
RESERVED
BIT 7
BIT 0
BIT 7
LOSC: LOS Configuration. Defines the source for the LOSOUT pin (see Figure 14).
0 = LOS LO alarm is used as the source.
1 = (Default) LOS input pin is used as the source.
BIT 6
RESERVED
BIT 5
INV LOS: Inverts the buffered input pin LOS to output pin LOSOUT (see Figure 14).
0 = Noninverted LOS to LOSOUT pin.
1 = Inverted LOS to LOSOUT pin.
BIT 4
ASEL: Address Select.
0 = Device address is A2h.
1 = Byte DEVICE ADDRESS in Table 02h, Register 8Ch is used as the device address.
BIT 3
MASK:
0 = Alarm-enable row exists at Table 01h, Registers F8h–FFh. Table 05h, Registers F8h–FFh are
empty.
1 = Alarm-enable row exists at Table 05h, Registers F8h–FFh. Table 01h, Registers F8h–FFh are
empty.
BIT 2
INVRSOUT: Allow for inversion of RSELOUT pin (see Figure 14).
0 = RSELOUT is not inverted.
1 = RSELOUT is inverted.
BITS 1:0
58
RESERVED
RESERVED
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
8Ah
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
IN1C
INVOUT1
RESERVED
RESERVED
RESERVED
ALATCH
DS1873
Table 02h, Register 8Ah: CNFGB
QTLATCH
BIT 7
BIT 0
BIT 7
IN1C: IN1 Software Control Bit (see Figure 14).
0 = IN1 pin’s logic controls OUT1 pin.
1 = OUT1 is active (bit 6 defines the polarity).
BIT 6
INVOUT1: Inverts the active state for OUT1 (see Figure 14).
0 = Noninverted.
1 = Inverted.
BITS 5:3
WLATCH
RESERVED
BIT 2
ALATCH: ADC Alarm’s Comparison Latch. Table 01h, Registers 70h–71h.
0 = ADC alarm and flags reflect the status of the last comparison.
1 = ADC alarm flags remain set.
BIT 1
QTLATCH: Quick Trip’s Comparison Latch. Table 01h, Registers 72h–73h and 76h.
0 = QT alarm and warning flags reflect the status of the last comparison.
1 = QT alarm and warning flags remain set.
BIT 0
WLATCH: ADC Warning’s Comparison Latch. Table 01h, Registers 74h–75h.
0 = ADC warning flags reflect the status of the last comparison.
1 = ADC warning flags remain set.
______________________________________________________________________________________
59
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register 8Bh: CNFGC
8Bh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
XOVEREN
RESERVED
TXDM34
TXDFG
TXDFLT
TXDIO
RSSI_FC
BIT 7
BIT 0
BIT 7
XOVEREN: Enables RSSI conversion to use the XOVER FINE (Table 02h, Register 90h–91h) value
during MON3 conversions.
0 = Uses hysteresis for linear RSSI measurements.
1 = XOVER value is enabled for nonlinear RSSI measurements.
BIT 6
RESERVED
BIT 5
TXDM34: Enables TXD to reset alarms, warnings, and quick trips associated to MON3 and MON4
during a TXD event.
0 = TXD event has no effect on the MON3 and MON4 alarms, warnings, and quick trips.
1 = MON3 and MON4 alarms, warnings, and quick trips are reset during a TXD event.
BIT 4
TXDFG: See Figure 13.
0 = FETG, an internal signal, has no effect on TXDOUT.
1 = FETG is enabled and ORed with other possible signals to create TXDOUT.
BIT 3
TXDFLT: See Figure 13.
0 = TXF pin has no effect on TXDOUT.
1 = TXF pin is enabled and ORed with other possible signals to create TXDOUT.
BIT 2
TXDIO: See Figure 13.
0 = (Default) TXD input signal is enabled and ORed with other possible signals to create TXDOUT.
1 = TXD input signal has no effect on TXDOUT.
BITS 1:0
60
RSSI_FF
RSSI_FC and RSSI_FF: RSSI Force Coarse and RSSI Force Fine. Control bits for RSSI mode of
operation on the MON3 conversion.
00b = Normal RSSI mode of operation (default).
01b = The fine settings of scale and offset are used for MON3 conversions.
10b = The coarse settings of scale and offset are used for MON3 conversions.
11b = Normal RSSI mode of operation.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
DS1873
Table 02h, Register 8Ch: DEVICE ADDRESS
8Ch
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
27
26
25
24
23
22
21
BIT 7
20
BIT 0
This value becomes the I2C slave address for the main memory when the ASEL (Table 02h, Register 89h) bit is
set. If A0h is programmed to this register, the auxiliary memory is disabled.
Table 02h, Register 8Dh: RIGHT-SHIFT2 (RSHIFT2)
8Dh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
RESERVED
BIT 7
RESERVED
RESERVED
RESERVED
RESERVED
MON3C2
MON3C1
MON3C0
BIT 0
Allows for right-shifting the final answer of MON3 coarse voltage measurement. This allows for scaling the
measurement to the smallest full-scale voltage and then right-shifting the final result so the reading is weighted to
the correct LSB.
______________________________________________________________________________________
61
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register 8Eh: RIGHT-SHIFT1 (RSHIFT1)
8Eh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
RESERVED
MON12
MON11
MON10
RESERVED
MON22
MON21
BIT 7
MON20
BIT 0
Allows for right-shifting the final answer of MON1 and MON2 voltage measurements. This allows for scaling the
measurements to the smallest full-scale voltage and then right-shifting the final result so the reading is weighted
to the correct LSB.
Table 02h, Register 8Fh: RIGHT-SHIFT0 (RSHIFT0)
8Fh
FACTORY DEFAULT
30h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
RESERVED
MON3F2
MON3F1
MON3F0
RESERVED
MON42
MON41
BIT 7
MON40
BIT 0
Allows for right-shifting the final answer of MON3 fine and MON4 voltage measurements. This allows for scaling
the measurements to the smallest full-scale voltage and then right-shifting the final result so the reading is
weighted to the correct LSB. The MON3 right-shifting is only available for the fine mode of operation. The coarse
mode does not right-shift.
62
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
FACTORY DEFAULT
0000h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
DS1873
Table 02h, Register 90h–91h: XOVER COARSE
90h
215
214
213
212
211
210
29
28
91h
27
26
25
24
23
22
21
0
BIT 7
BIT 0
Defines the crossover value for RSSI measurements of nonlinear inputs when XOVEREN is set to a 1 (Table 02h,
Register 8Bh). MON3 coarse conversion results (before right-shifting) less than this register are clamped to the
value of this register.
Table 02h, Register 92h–93h: VCC SCALE
Table 02h, Register 94h–95h: MON1 SCALE
Table 02h, Register 96h–97h: MON2 SCALE
Table 02h, Register 98h–99h: MON3 FINE SCALE
Table 02h, Register 9Ah–9Bh: MON4 SCALE
Table 02h, Register 9Ch–9Dh: MON3 COARSE SCALE
FACTORY CALIBRATED
92h, 94h,
96h, 98h,
9Ah, 9Ch
93h, 95h,
97h, 99h,
9Bh, 9Dh
READ ACCESS
PW2 or (PW1 and RWTBL246) or (PW1 and RTBL246)
WRITE ACCESS
PW2 or (PW1 and RWTBL246)
MEMORY TYPE
Nonvolatile (SEE)
215
214
213
212
211
210
29
28
27
26
25
24
23
22
21
20
BIT 7
BIT 0
Controls the scaling or gain of the FS voltage measurements. The factory-calibrated value produces an FS
voltage of 6.5536V for VCC; 2.5V for MON1, MON2, MON4; and 0.3125V for MON3 fine.
______________________________________________________________________________________
63
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register 9Eh–9Fh: RESERVED
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
These registers are reserved.
Table 02h, Register A0h–A1h: XOVER FINE
FACTORY DEFAULT
FFFFh
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
A0h
215
214
213
212
211
210
29
28
A1h
27
26
25
24
23
22
21
0
BIT 7
BIT 0
Defines the crossover value for RSSI measurements of nonlinear inputs when XOVEREN is set to a 1 (Table 02h,
Register 8Bh). MON3 fine conversion results (before right-shifting) greater than this register require a MON3
coarse conversion.
64
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
A2h, A4h,
A6h, A8h,
AAh, ACh
A3h, A5h,
A7h, A9h,
ABh, ADh
DS1873
Table 02h, Register A2h–A3h: VCC OFFSET
Table 02h, Register A4h–A5h: MON1 OFFSET
Table 02h, Register A6h–A7h: MON2 OFFSET
Table 02h, Register A8h–A9h: MON3 FINE OFFSET
Table 02h, Register AAh–ABh: MON4 OFFSET
Table 02h, Register ACh–ADh: MON3 COARSE OFFSET
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
S
S
215
214
213
212
211
210
29
28
27
26
25
24
23
22
BIT 7
BIT 0
Allows for offset control of these voltage measurements if desired. This number is two’s complement.
Table 02h, Register AEh–AFh: INTERNAL TEMP OFFSET
FACTORY CALIBRATED
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
AEh
S
28
27
26
25
24
23
22
AFh
21
20
2-1
2-2
2-3
2-4
2-5
2-6
BIT 7
BIT 0
Allows for offset control of temperature measurement if desired. The final result must be XORed with BB40h
before writing to this register. Factory calibration contains the desired value for a reading in degrees Celsius.
______________________________________________________________________________________
65
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register B0h–B3h: PW1
FACTORY DEFAULT
FFFF FFFFh
READ ACCESS
N/A
WRITE ACCESS
PW2 or (PW1 and WPW1)
MEMORY TYPE
Nonvolatile (SEE)
B0h
231
230
229
228
227
226
225
224
B1h
223
222
221
220
219
218
217
216
B2h
215
214
213
212
211
210
29
28
B3h
27
26
25
24
23
22
21
20
BIT 7
BIT 0
The PWE value is compared against the value written to this location to enable PW1 access. At power-on, the
PWE value is set to all ones. Thus, writing these bytes to all ones grants PW1 access on power-on without
writing the password entry. All reads of this register are 00h.
Table 02h, Register B4h–B7h: PW2
FACTORY DEFAULT
FFFF FFFFh
READ ACCESS
N/A
WRITE ACCESS
PW2
MEMORY TYPE
Nonvolatile (SEE)
B4h
231
230
229
228
227
226
225
224
B5h
223
222
221
220
219
218
217
216
B6h
215
214
213
212
211
210
29
28
B7h
27
26
25
24
23
22
21
20
BIT 7
BIT 0
The PWE value is compared against the value written to this location to enable PW2 access. At power-on, the
PWE value is set to all ones. Thus, writing these bytes to all ones grants PW2 access on power-on without
writing the password entry. All reads of this register are 00h.
66
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
B8h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
RESERVED
HLOS2
HLOS1
HLOS0
RESERVED
LLOS2
DS1873
Table 02h, Register B8h: LOS RANGING
LLOS21
BIT 7
LLOS0
BIT 0
This register controls the full-scale range of the quick-trip monitoring for the differential input’s of MON3.
BIT 7
RESERVED (Default = 0)
HLOS[2:0]: HLOS Full-Scale Ranging. 3-bit value to select the FS comparison voltage for high LOS
found on MON3. Default is 000b and creates an FS of 1.25V.
BITS 6:4
BIT 3
HLOS[2:0]
% of 1.25V
FS Voltage
000b
100.00
1.250
001b
80.00
1.000
010b
66.67
0.833
011b
50.00
0.625
100b
40.00
0.500
101b
33.33
0.417
110b
28.57
0.357
111b
25.00
0.313
RESERVED (Default = 0)
LLOS[2:0]: LLOS Full-Scale Ranging. 3-bit value to select the FS comparison voltage for low LOS
found on MON3. Default is 000b and creates an FS of 1.25V.
BITS 2:0
LLOS[2:0]
% of 1.25V
FS Voltage
000b
100.00
1.250
001b
80.00
1.000
010b
66.67
0.833
011b
50.00
0.625
100b
40.00
0.500
101b
33.33
0.417
110b
28.57
0.357
111b
25.00
0.313
______________________________________________________________________________________
67
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register B9h: COMP RANGING
B9h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
RESERVED
HBIAS2
HBIAS1
HBIAS0
RESERVED
APC2
APC1
BIT 7
APC0
BIT 0
The upper nibble of this byte controls the full-scale range of the quick-trip monitoring for BIAS. The lower nibble of
this byte controls the full-scale range for the quick-trip monitoring of the APC reference as well as the closed-loop
monitoring of APC.
BIT 7
RESERVED (Default = 0)
HBIAS[2:0]: HBIAS Full-Scale Ranging. 3-bit value to select the FS comparison voltage for BIAS
found on MON1. Default is 000b and creates an FS of 1.25V.
BITS 6:4
BIT 3
BIAS[2:0]
% of 1.25V
FS Voltage
000b
100.00
1.250
001b
80.00
1.000
010b
66.67
0.833
011b
50.00
0.625
100b
40.00
0.500
101b
33.33
0.417
110b
28.57
0.357
111b
25.00
0.313
RESERVED (Default = 0)
APC[2:0]: APC Full-Scale Ranging. 3-bit value to select the FS comparison voltage for MON2 with
the APC. Default is 000b and creates an FS of 2.5V.
BITS 2:0
68
APC[2:0]
% of 2.50V
FS Voltage
000b
100.00
2.500
001b
80.00
2.000
010b
66.67
1.667
011b
50.00
1.250
100b
40.00
1.000
101b
33.33
0.833
110b
28.57
0.714
111b
25.00
0.625
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
BAh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
29
28
27
26
25
DS1873
Table 02h, Register BAh: IBIASMAX
24
23
BIT 7
22
BIT 0
This value defines the maximum DAC value allowed for the upper 8 bits of BIAS output during APC closed-loop
operations. During the intial step and binary search, this value does not cause an alarm, but does still clamp the
BIAS DAC value. After the startup sequence (or normal APC operations), if the APC loop tries to create a BIAS
value greater than this setting, it is clamped and creates a MAX BIAS alarm.
Table 02h, Register BBh: ISTEP
BBh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
29
BIT 7
28
27
26
25
24
23
22
BIT 0
The initial step value used at power-on or after a TXD pulse to control the BIAS DAC. At startup, this value plus
20 = 1 is continuously added to the BIAS DAC value until the APC feedback (MON2) is greater than its threshold.
At that time, a binary search is used to complete the startup of the APC closed loop. If the resulting math
operation is greater than IBIASMAX (Table 02h, Register BAh), the result is not loaded into the BIAS DAC, but the
binary search is begun to complete the initial search for APC. During startup, the BIAS DAC steps causing a
higher bias value than IBIASMAX do not create the BIAS MAX alarm. The BIAS MAX alarm detection is enabled at
the end of the binary search.
______________________________________________________________________________________
69
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register BCh: HTXP
BCh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
27
26
25
24
23
22
21
BIT 7
20
BIT 0
Fast-comparison DAC threshold adjust for high TXP. This value is added to the APC DAC value recalled from
Table 04h. If the sum is greater than 0xFF, 0xFF is used. Comparisons greater than VHTXP, compared against
VMON2, create a TXP HI alarm. The same ranging applied to the APC DAC should be used here.
Full Scale
VHTXP =
(HTXP + APC DAC)
255
Table 02h, Register BDh: LTXP
BDh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
27
26
25
24
23
22
21
BIT 7
20
BIT 0
Fast-comparison DAC threshold adjust for low TXP. This value is subtracted from the APC DAC value recalled
from Table 04h. If the difference is less than 0x00, 0x00 is used. Comparisons less than VLTXP, compared
against VMON2, create a TXP LO alarm. The same ranging applied to the APC DAC should be used here.
Full Scale
VLTXP =
( APC DAC LTXP )
255
70
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
DS1873
Table 02h, Register BEh: HLOS
BEh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
27
26
25
24
23
22
21
BIT 7
20
BIT 0
Fast-comparison DAC threshold adjust for high LOS. The combination of HLOS and LLOS creates a hysteresis
comparator. As RSSI falls below the LLOS threshold, the LOS LO alarm bit is set to 1. The LOS alarm remains set
until the RSSI input is found above the HLOS threshold setting, which clears the LOS LO alarm bit and sets the
LOS HI alarm bit. At power-on, both LOS LO and LOS HI alarm bits are 0 and the hysteresis comparator uses the
LLOS threshold setting.
Table 02h, Register BFh: LLOS
BFh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
27
BIT 7
26
25
24
23
22
21
20
BIT 0
Fast-comparison DAC threshold adjust for low LOS. See HLOS (Table 02h, Register BEh) for functional description.
______________________________________________________________________________________
71
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register C0h: PW_ENA
C0h
FACTORY DEFAULT
10h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
RWTBL78
RWTBL1C
RWTBL2
RWTBL1A
RWTBL1B
WLOWER
WAUXA
BIT 7
72
WAUXB
BIT 0
BIT 7
RWTBL78: Tables 07h–08h
0 = (Default) Read and write access for PW2 only.
1 = Read and write access for both PW1 and PW2.
BIT 6
RWTBL1C: Table 01h or 05h bytes F8h–FFh. Table address is dependent on MASK bit (Table 02h,
Register 89h).
0 = (Default) Read and write access for PW2 only.
1 = Read and write access for both PW1 and PW2.
BIT 5
RWTBL2: Tables 02h. Writing a nonvolatile value to this bit requires PW2 access.
0 = (Default) Read and write access for PW2 only.
1 = Read and write access for both PW1 and PW2.
BIT 4
RWTBL1A: Table 01h, Registers 80h–BFh
0 = Read and write access for PW2 only.
1 = (Default) Read and write access for both PW1 and PW2.
BIT 3
RWTBL1B: Table 01h, Registers C0h–F7h
0 = (Default) Read and write access for PW2 only.
1 = Read and write access for both PW1 and PW2.
BIT 2
WLOWER: Bytes 00h–5Fh in main memory. All users can read this area.
0 = (Default) Write access for PW2 only.
1 = Write access for both PW1 and PW2.
BIT 1
WAUXA: Auxiliary Memory, Registers 00h–7Fh. All users can read this area.
0 = (Default) Write access for PW2 only.
1 = Write access for both PW1 and PW2.
BIT 0
WAUXB: Auxiliary Memory, Registers 80h–FFh. All users can read this area.
0 = (Default) Write access for PW2 only.
1 = Write access for both PW1 and PW2.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
C1h
FACTORY DEFAULT
03h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
RWTBL46
RTBL1C
RTBL2
RTBL1A
RTBL1B
WPW1
DS1873
Table 02h, Register C1h: PW_ENB
WAUXAU
BIT 7
WAUXBU
BIT 0
BIT 7
RWTBL46: Tables 04h and 06h
0 = (Default) Read and write access for PW2 only.
1 = Read and write access for PW1.
BIT 6
RTBL1C: Table 01h or Table 05h, Registers F8h–FFh. Table address is dependent on MASK bit
(Table 02h, Register 89h).
0 = (Default) Read and write access for PW2 only.
1 = Read access for PW1.
BIT 5
RTBL2: Table 02h
0 = (Default) Read and write access for PW2 only.
1 = Read access for PW1.
BIT 4
RTBL1A: Table 01h, Registers 80h–BFh
0 = (Default) Read and write access for PW2 only.
1 = Read access for PW1.
BIT 3
RTBL1B: Table 01h, Registers C0h–F7h
0 = (Default) Read and write access for PW2 only.
1 = Read access for PW1.
BIT 2
WPW1: Register PW1 (Table 02h, Registers B0h–B3h). For security purposes these registers are
not readable.
0 = (Default) Write access for PW2 only.
1 = Write access for PW1.
BIT 1
WAUXAU: Auxiliary Memory, Registers 00h–7Fh. All users can read this area.
0 = Write access for PW2 only.
1 = (Default) Write access for user, PW1 and PW2.
BIT 0
WAUXBU: Auxiliary Memory, Registers 80h–FFh. All users can read this area.
0 = Write access for PW2 only.
1 = (Default) Write access for user, PW1 and PW2.
Table 02h, Register C2h–C5h: RESERVED
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
These registers are reserved.
______________________________________________________________________________________
73
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register C6h: POLARITY
C6h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
RESERVED
RESERVED
RESERVED
RESERVED
MODP
BIASP
DAC1P
BIT 7
BITS 7:4
74
DAC2P
BIT 0
RESERVED
BIT 3
MODP: MOD DAC Polarity. The MOD DAC (Table 02h, Registers 82h–83h) range is 000h–3FFh. A
setting of 000h creates a pulse density of zero and 3FFh creates a pulse density of 1023/1024. This
polarity bit allows the user to use GND or VREFIN as the reference. The power-on of MOD DAC is 000h,
thus an application that needs VREFIN to be in off state should use the inverted polarity.
0 = Normal polarity. A setting of 000h results in a pulse-density output of zero held at GND and a
setting of 3FFh results in a pulsed-density output of 1023/1024 held mostly at VREFIN.
1 = Inverted polarity. A setting of 000h results in a pulse-density output of zero held at VREFIN and a
setting of 3FFh results in a pulsed-density output of 1023/1024 held mostly at GND.
BIT 2
BIASP: BIAS DAC Polarity. The BIAS DAC (Table 02h, Registers CA–CBh) range is 000h–3FFh. A
setting of 000h creates a pulse density of zero and 3FFh creates a pulse density of 1023/1024. This
polarity bit allows the user to use GND or VREFIN as the reference. The power-on of BIAS DAC is 000h,
thus an application that needs VREFIN to be the off state should use the inverted polarity.
0 = Normal polarity. A setting of 000h results in a pulse-density output of zero held at GND and a
setting of 3FFh results in a pulsed-density output of 1023/1024 held mostly at VREFIN.
1 = Inverted polarity. A setting of 000h results in a pulse-density output of zero held at VREFIN and a
setting of 3FFh results in a pulsed-density output of 1023/1024 held mostly at GND.
BIT 1
DAC1P: DAC1 VALUE Polarity. The DAC1 VALUE (Table 02h, Registers 84h–85h) range is 000h–
3FFh. A setting of 000h creates a pulse density of zero and 3FFh creates a pulse density of
1023/1024. This polarity bit allows the user to use GND or VREFIN as the reference. The power-on of
DAC1 VALUE is 000h, thus an application that needs VREFIN to be the off state should use the
inverted polarity.
0 = Normal polarity. A setting of 000h results in a pulse-density output of zero held at GND and a
setting of 3FFh results in a pulsed-density output of 1023/1024 held mostly at VREFIN.
1 = Inverted polarity. A setting of 000h results in a pulse-density output of zero held at VREFIN and a
setting of 3FFh results in a pulsed-density output of 1023/1024 held mostly at GND.
BIT 0
DAC2P: DAC2 VALUE Polarity. The DAC2 VALUE (Table 02h, Registers 86h–87h) range is 000h–
3FFh. A setting of 000h creates a pulse-density of zero and 3FFh creates a pulse density of
1023/1024. This polarity bit allows the user to use GND or VREFIN as the reference. The power-on of
DAC2 VALUE is 000h, thus an application that needs VREFIN to be the off state should use the
inverted polarity.
0 = Normal polarity. A setting of 000h results in a pulse-density output of zero held at GND and a
setting of 3FFh results in a pulsed-density output of 1023/1024 held mostly at VREFIN.
1 = Inverted polarity. A setting of 000h results in a pulse-density output of zero held at VREFIN and a
setting of 3FFh results in a pulsed-density output of 1023/1024 held mostly at GND.
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
C7h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
PW2 or (PW1 and RWTBL2)
MEMORY TYPE
Nonvolatile (SEE)
27
26
25
24
23
DS1873
Table 02h, Register C7h: TBLSELPON
22
21
BIT 7
20
BIT 0
Chooses the initial value for the table-select byte (Lower Memory, Register 7Fh) at power-on.
Table 02h, Register C8h–C9h: MAN BIAS
FACTORY DEFAULT
0000h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
(PW2 and BIAS EN = 0) or (PW1 and RWTBL2 and BIAS EN = 0)
MEMORY TYPE
Volatile
C8h
0
0
0
0
0
0
0
28
C9h
27
26
25
24
23
22
21
20
BIT 7
BIT 0
When BIAS EN (Table 02h, Register 80h) is written to 0, writes to these bytes control the BIAS DAC.
Table 02h, Register CAh: MAN_CNTL
CAh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
(PW2 and BIAS EN = 0) or (PW1 and RWTBL2 and BIAS EN = 0)
MEMORY TYPE
Volatile
RESERVED
BIT 7
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
MAN_CLK
BIT 0
When BIAS EN (Table 02h, Register 80h) is written to 0, MAN_CLK controls the updates of the MAN BIAS value to
the BIAS DAC. The values of MAN BIAS must be written with a separate write command. Setting MAN_CLK to a 1
clocks the MAN BIAS value to the BIAS DAC.
1) Write the MAN BIAS value with a write command.
2) Set the MAN_CLK bit to a 1 with a separate write command.
3) Clear the MAN_CLK bit to a 0 with a separate write command.
______________________________________________________________________________________
75
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register CBh–CCh: BIAS DAC
FACTORY DEFAULT
0000h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
N/A
MEMORY TYPE
Volatile
CBh
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
RESERVED
29
28
CCh
27
26
25
24
23
22
21
20
BIT 7
BIT 0
The digital value used for BIAS and resolved from the APC. This register is updated after each decision of the
APC loop.
Table 02h, Register CDh: RESERVED
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
N/A
MEMORY TYPE
N/A
This register is reserved.
Table 02h, Register CEh: DEVICE ID
CEh
FACTORY DEFAULT
73h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
N/A
MEMORY TYPE
ROM
0
1
1
1
0
0
1
BIT 7
Hardwired connections to show the device ID.
76
______________________________________________________________________________________
1
BIT 0
SFP+ Controller with Analog LDD Interface
FACTORY DEFAULT
DEVICE VERSION
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
N/A
MEMORY TYPE
ROM
CFh
DS1873
Table 02h, Register CFh: DEVICE VER
DEVICE VERSION
BIT 7
BIT 0
Hardwired connections to show the device version.
Table 02h, Register D0h: APC DAC
D0h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
(PW2 and ACPEN = 0) or (PW1 and RWTBL2 and APC EN = 0)
MEMORY TYPE
Volatile
27
BIT 7
26
25
24
23
22
21
20
BIT 0
The digital value used for APC reference and recalled from Table 06h at the adjusted memory address found in
TINDEX. This register is updated at the end of the temperature conversion.
______________________________________________________________________________________
77
DS1873
SFP+ Controller with Analog LDD Interface
Table 02h, Register D1h: HBIAS DAC
D1h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
(PW2 and APC EN = 0) or (PW1 & RWTBL2 and APC EN = 0)
MEMORY TYPE
Volatile
27
26
25
24
23
22
21
BIT 7
20
BIT 0
The digital value used for HBIAS reference and recalled from Table 06h at the adjusted memory address found
in TINDEX. This register is updated at the end of the temperature conversion.
Table 02, Register D2h–D7h: RESERVED
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL2) or (PW1 and RTBL2)
WRITE ACCESS
N/A
MEMORY TYPE
N/A
These registers are reserved.
Table 02h, Register D8h–F7h: EMPTY
FACTORY DEFAULT
00h
READ ACCESS
N/A
WRITE ACCESS
N/A
MEMORY TYPE
None
These registers do not exist.
78
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
Table 04h, Register 80h–C7h: MODULATION LUT
80h–C7h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL46) or (PW1 and RTBL46)
WRITE ACCESS
PW2 or (PW1 and RWTBL46)
MEMORY TYPE
Nonvolatile (EE)
27
26
25
24
23
22
21
BIT 7
20
BIT 0
The digital value for the modulation DAC output.
The MODULATION LUT is a set of registers assigned to hold the temperature profile for the MOD DAC. The
values in this table determine the set point for the modulation voltage. The temperature measurement is used to
index the LUT (TINDEX, Table 02h, Register 81h) in 2°C increments from -40°C to +102°C, starting at 80h in
Table 04h. Register 80h defines the -40°C to -38°C MOD output, Register 81h defines the -38°C to -36°C MOD
output, and so on. Values recalled from this EEPROM memory table are written into the MOD DAC (Table 02h,
Register 82h–83h) location that holds the value until the next temperature conversion. The DS1873 can be
placed into a manual mode (MOD EN bit, Table 02h, Register 80h), where the MOD DAC is directly controlled for
calibration. If the temperature compensation functionality is not required, then program the entire Table 04h to the
desired modulation setting.
Table 04h, Register F8h–FFh: MOD OFFSET LUT
F8h–FFh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL46) or (PW1 and RTBL46)
WRITE ACCESS
PW2 or (PW1 and RWTBL46)
MEMORY TYPE
Nonvolatile (EE)
29
28
27
26
25
BIT 7
24
23
22
BIT 0
The digital value for the temperature offset of the MOD DAC output.
F8h
Less than or equal to -8°C
F9h
Greater than -8°C up to +8°C
FAh
Greater than +8°C up to +24°C
FBh
Greater than +24°C up to +40°C
FCh
Greater than +40°C up to +56°C
FDh
Greater than +56°C up to +72°C
FEh
Greater than +72°C up to +88°C
FFh
Greater than +88°C
The MOD DAC is a 10-bit register. The MODULATION LUT is an 8-bit LUT. The MOD OFFSET LUT times 4 plus
the MODULATION LUT makes use of the entire 10-bit range.
______________________________________________________________________________________
79
DS1873
Table 04h Register Description
DS1873
SFP+ Controller with Analog LDD Interface
Table 06h Register Descriptions
Table 06h, Register 80h–A3h: APC TE LUT
80h–A3h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL46) or (PW1 and RTBL46)
WRITE ACCESS
PW2 or (PW1 and RWTBL46)
MEMORY TYPE
Nonvolatile (EE)
27
26
25
24
23
22
21
BIT 7
20
BIT 0
The APC TE LUT is a set of registers assigned to hold the temperature profile for the APC reference DAC. The
values in this table combined with the APC bits in the COMP RANGING register (Table 02h, Register B9h)
determine the set point for the APC loop. The temperature measurement is used to index the LUT (TINDEX, Table
02h, Register 81h) in 4°C increments from -40°C to +100°C, starting at Register 80h in Table 05h. Register 80h
defines the -40°C to -36°C APC reference value, Register 81h defines the -36°C to -32°C APC reference value,
and so on. Values recalled from this EEPROM memory table are written into the APC DAC (Table 02h, Register
CDh) location that holds the value until the next temperature conversion. The DS1873 can be placed into a
manual mode (APC EN bit, Table 02h, Register 80h), where APC DAC can be directly controlled for calibration. If
TE temperature compensation is not required by the application, program the entire LUT to the desired APC set
point.
Table 06h, Register A4h–A7h: RESERVED
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL46) or (PW1 and RTBL46)
WRITE ACCESS
PW2 or (PW1 and RWTBL46)
MEMORY TYPE
Nonvolatile (EE)
These registers are reserved.
80
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
DS1873
Table 06h, Register F8h–FFh: HBIAS LUT
F8h–FFh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL46) or (PW1 and RTBL46)
WRITE ACCESS
PW2 or (PW1 and RWTBL46)
MEMORY TYPE
Nonvolatile (EE)
27
26
25
24
23
22
21
BIT 7
20
BIT 0
High bias alarm threshold (HBATH) is a digital clamp used to ensure that the DAC setting for BIAS currents does
not exceed a set value. The table below shows the range of temp for each byte’s location. The table shows a
rising temperature; for a falling temperature there is 1°C of hysteresis.
F8h
Less than or equal to -8°C
F9h
Greater than -8°C up to +8°C
FAh
Greater than +8°C up to +24°C
FBh
Greater than +24°C up to +40°C
FCh
Greater than +40°C up to +56°C
FDh
Greater than +56°C up to +72°C
FEh
Greater than +72°C up to +88°C
FFh
Greater than +88°C
Table 07h Register Descriptions
Table 07h, Register 80h–C7h: DAC1 LUT
80h–C7h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL78) and (PW1 and RTBL78)
WRITE ACCESS
PW2 or (PW1 and RWTBL78)
MEMORY TYPE
Nonvolatile (EE)
27
BIT 7
26
25
24
23
22
21
20
BIT 0
The DAC1 LUT is a set of registers assigned to hold the PWM profile for DAC1. The values in this table
determine the set point for DAC1. The temperature measurement is used to index the LUT (TINDEX, Table 02h,
Register 81h) in 2°C increments from -40°C to +102°C, starting at Register 80h in Table 07h. Register 80h
defines the -40°C to -38°C DAC1 value, Register 81h defines -38°C to -36°C DAC1 value, and so on. Values
recalled from this EEPROM memory table are written into the DAC1 VALUE (Table 02h, Registers 84h–85h)
location, which holds the value until the next temperature conversion. The part can be placed into a manual
mode (DAC1 EN bit, Table 02h, Register 80h), where DAC1 can be directly controlled for calibration. If
temperature compensation is not required by the application, program the entire LUT to the desired DAC1 set
point.
______________________________________________________________________________________
81
DS1873
SFP+ Controller with Analog LDD Interface
Table 07h, Register C8h–F7h: RESERVED
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL78) or (PW1 and RTBL78)
WRITE ACCESS
PW2 or (PW1 and RWTBL78)
MEMORY TYPE
Nonvolatile (EE)
These registers are reserved.
Table 07h, Register F8h–FFh: DAC1 OFFSET LUT
F8h–FFh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL78) or (PW1 and RTBL78)
WRITE ACCESS
PW2 or (PW1 and RWTBL78)
MEMORY TYPE
Nonvolatile (EE)
29
28
27
26
25
24
23
BIT 7
22
BIT 0
The digital value for the temperature offset of the DAC1 output.
F8h
Less than or equal to -8°C
F9h
Greater than -8°C up to +8°C
FAh
Greater than +8°C up to +24°C
FBh
Greater than +24°C up to +40°C
FCh
Greater than +40°C up to +56°C
FDh
Greater than +56°C up to +72°C
FEh
Greater than +72°C up to +88°C
FFh
Greater than +88°C
The DAC1 VALUE is a 10-bit register. The DAC1 LUT is an 8-bit LUT. The DAC1 OFFSET LUT times 4 plus the
MODULATION LUT makes use of the entire 10-bit range.
82
______________________________________________________________________________________
SFP+ Controller with Analog LDD Interface
Table 08h, Register 80h–A3h: DAC2 LUT
80h–A3h
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL78) or (PW1 and RTBL78)
WRITE ACCESS
PW2 or (PW1 and RWTBL78)
MEMORY TYPE
Nonvolatile (EE)
27
26
25
24
23
22
BIT 7
21
20
BIT 0
The DAC2 LUT is set of registers assigned to hold the PWM profile for DAC2. The values in this table determine
the set point for DAC2. The temperature measurement is used to index the LUT (TINDEX, Table 02h, Register
81h) in 4°C increments from -40°C to +100°C, starting at Register 80h in Table 07h. Register 80h defines the
-40°C to -36°C DAC2 value, Register 81h defines -36°C to -32°C DAC2 value, and so on. Values recalled from
this EEPROM memory table are written into the DAC2 VALUE (Table 02h, Registers 86h–87h) location that holds
the value until the next temperature conversion. The DS1873 can be placed into a manual mode (DAC2 EN bit,
Table 02h, Register 80h), where DAC2 can be directly controlled for calibration. If temperature compensation is
not required by the application, program the entire LUT to the desired DAC2 set point.
Table 08h, Register A4h–A7h: RESERVED
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL78) or (PW1 and RTBL78)
WRITE ACCESS
PW2 or (PW1 and RWTBL78)
MEMORY TYPE
Nonvolatile (EE)
These registers are reserved.
______________________________________________________________________________________
83
DS1873
Table 08h Register Descriptions
DS1873
SFP+ Controller with Analog LDD Interface
Table 08h, Register F8h–FFh: DAC2 OFFSET LUT
F8h–FFh
FACTORY DEFAULT
00h
READ ACCESS
PW2 or (PW1 and RWTBL78) or (PW1 and RTBL78)
WRITE ACCESS
PW2 or (PW1 and RWTBL78)
MEMORY TYPE
Nonvolatile (EE)
29
28
27
26
25
24
23
BIT 7
22
BIT 0
The digital value for the temperature offset of the DAC2 output.
F8h
Less than or equal to -8°C
F9h
Greater than -8°C up to +8°C
FAh
Greater than +8°C up to +24°C
FBh
Greater than +24°C up to +40°C
FCh
Greater than +40°C up to +56°C
FDh
Greater than +56°C up to +72°C
FEh
Greater than +72°C up to +88°C
FFh
Greater than +88°C
The DAC2 VALUE is a 10-bit register. The DAC2 LUT is an 8-bit LUT. The DAC2 OFFSET LUT times 4 plus the
MODULATION LUT makes use of the entire 10-bit range.
Auxiliary Memory A0h Register Descriptions
Auxiliary Memory A0h, Register 00h–7Fh: EEPROM
00h–7Fh
FACTORY DEFAULT
00h
READ ACCESS
ALL
WRITE ACCESS
PW2 or (PW1 and WAUXA) or (WAUXAU)
MEMORY TYPE
Nonvolatile (EE)
27
26
25
24
23
22
21
BIT 7
Accessible with the slave address A0h.
84
______________________________________________________________________________________
20
BIT 0
SFP+ Controller with Analog LDD Interface
DS1873
Auxiliary Memory A0h, Register 80h–FFh: EEPROM
80h–FFh
FACTORY DEFAULT
00h
READ ACCESS
ALL
WRITE ACCESS
PW2 or (PW1 and RWAUXB) or (RWAUXBU)
MEMORY TYPE
Nonvolatile (EE)
27
26
25
24
23
22
21
BIT 7
20
BIT 0
Accessible with the slave address A0h.
Applications Information
Power-Supply Decoupling
To achieve best results, it is recommended that the power
supply is decoupled with a 0.01µF or a 0.1µF capacitor.
Use high-quality, ceramic, surface-mount capacitors,
and mount the capacitors as close as possible to the
VCC and GND pins to minimize lead inductance.
SDA and SCL Pullup Resistors
SDA is an open-collector output on the DS1873 that
requires a pullup resistor to realize high logic levels. A
master using either an open-collector output with a
pullup resistor or a push-pull output driver can be utilized for SCL. Pullup resistor values should be chosen
to ensure that the rise and fall times listed in the I2C AC
Electrical Characteristics table are within specification.
Package Information
For the latest package outline information and land patterns, go to www.maxim-ic.com/packages. Note that a “+”, “#”, or “-” in the
package code indicates RoHS status only. Package drawings may show a different suffix character, but the drawing pertains to the
package regardless of RoHS status.
PACKAGE TYPE
PACKAGE CODE
DOCUMENT NO.
28 TQFN-EP
T2855+6
21-0140
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implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
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