DtSheet

MICREL MIC3003GFLTR

MIC3003GFL
FOM Management IC
with Internal Calibration
General Description
Features
The MIC3003GFL is a fiber optic module controller which
enables the implementation of sophisticated, hot-pluggable
fiber optic transceivers with intelligent laser control and an
internally calibrated Digital Diagnostic Monitoring Interface
per SFF-8472. It essentially integrates all non-data path
functions of an SFP/SFP+ transceiver into a tiny (3mm x 3mm)
MLF® package. It also works well as a microcontroller
peripheral in transponders or 10Gbps transceivers. The
MIC3003GFL uses the same die as the MIC3003 with all its
functions, but in a smaller package and different pin out.
A highly configurable automatic power control (APC) circuit
controls laser bias. Bias and modulation are temperature
compensated using dual DACs, an on-chip temperature
sensor, and NVRAM look-up tables. A programmable
internal feedback resistor provides a wide dynamic range for
the APC. Controlled laser turn-on.
An analog-to-digital converter converts the measured
temperature, voltage, bias current, transmit power, and
received power from analog to digital. An EEPOT provides
front-end adjustment of RX power. Each parameter is
compared against user-programmed warning and alarm
thresholds. Analog comparators and DACs provide fast
monitoring of received power and critical laser operating
parameters. Data can be reported as either internally
calibrated or externally calibrated.
An interrupt output, power-on hour meter, and data-ready
bits add user friendliness beyond SFF-8472. The interrupt
output and data-ready bits reduce overhead in the host
system. The power-on hour meter logs operating hours
using an internal real-time clock and stores the result in
NVRAM.
In addition to the features listed above, the MIC3003
features an extended temperature range, options to mask
alarms and warnings interrupt and TXFAULT, a reset signal
source, and the ability to support up to four chips with the
same address on the serial interface. It also supports eightbyte SMBus block writes.
Communication with the MIC3003 is via an industry
standard 2-wire SMBus serial interface. Nonvolatile
memory is provided for serial ID, configuration, and
separate OEM and user scratchpad spaces.
Datasheets and support documentation can be found on
Micrel’s web site at: www.micrel.com.
• Packaged in a ultra small (3mm x 3mm) 24-pin MLF®
package
• Extended temperature range
• Alarms and warnings interrupt and TXFAULT masks
• Capability to support up to four devices on one SMBus
• APC or constant-current laser bias
• Turbo mode for APC loop start-up and shorter laser turn
on time
• Supports multiple laser types and bias circuit topologies
• Integrated digital temperature sensor
• Temperature compensation of modulation, bias, bias fault
and alarm thresholds via NVRAM look-up tables
• NVRAM to support GBIC/SFP serial ID function
• User writable EEPROM scratchpad
• Reset signal
requirements
compatible
with
some
new
systems
• Diagnostic monitoring interface per SFF-8472
– Monitors and reports critical parameters:
temperature, bias current, TX and RX optical power,
and supply voltage
– S/W control and monitoring of TXFAULT, RXLOS,
RATESELECT, and TXDISABLE
– Internal or external calibration
– EEPOT for adjusting RX power measurement
• Power-on hour meter
• Interrupt capability
• Extensive test and calibration features
• 2-wire SMBus-compatible serial interface
• SFP/SFP+ MSA and SFF-8472 compliant
• 3.0V to 3.6V power supply range
• 5V-tolerant I/O
Applications
•
•
•
•
•
•
SFP/SFP+ optical transceivers
SONET/SDH transceivers and transponders
Fibre Channel transceivers
10Gbps transceivers
Free space optical communications
Proprietary optical links
MLF and MicroLeadFrame are registered trademarks of Amkor Technology, Inc.
Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com
July, 2010
M9999-072910-A
[email protected] or (408) 955-1690
Micrel, Inc.
MIC3003GFL
Typical Application
Ordering Information
Part Number
Package Marking
MIC3003GFL
GFL 3003
with Pb-Free bar-line indicator
GFL 3003
with Pb-Free bar-line indicator
MIC3003GFLTR(1)
Junction Temp.
Range
–45°C to +105°C
Package Type
Lead Finish
24-pin (3mm x 3mm) MLF®
–45°C to +105°C
24-pin (3mm x 3mm) MLF®
Pb-Free,
NiPdAu
Pb-Free,
NiPdAu
Note:
1.
July 2010
Tape and Reel.
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MIC3003GFL
Contents
General Description .......................................................................................................................................................... 1
Features ............................................................................................................................................................................. 1
Pin Configuration .............................................................................................................................................................. 8
Pin Configuration .............................................................................................................................................................. 8
Pin Description (MIC3003GFL only) ................................................................................................................................ 8
Absolute Maximum Ratings ........................................................................................................................................... 10
Operating Ratings ........................................................................................................................................................... 10
Electrical Characteristics ............................................................................................................................................... 10
Electrical Characteristics ............................................................................................................................................... 12
Electrical Characteristics ............................................................................................................................................... 13
Serial Interface Timing Diagram .................................................................................................................................... 14
Serial Interface Address Maps....................................................................................................................................... 15
Block Diagram ................................................................................................................................................................. 18
Analog-to-Digital Converter/Signal Monitoring............................................................................................................ 18
Alarms and Warnings Interrupt Source Masking .......................................................................................................... 19
Alarms and Warnings as TXFAULT Source ................................................................................................................. 21
Latching of Alarms and Warnings................................................................................................................................. 21
SMBus Multipart Support.............................................................................................................................................. 21
QGOP Pin Function ...................................................................................................................................................... 21
Calibration Modes ........................................................................................................................................................... 22
A/ External Calibration .................................................................................................................................................. 22
Voltage.................................................................................................................................................................... 22
Temperature ........................................................................................................................................................... 22
Bias Current............................................................................................................................................................ 22
TX Power ................................................................................................................................................................ 22
RX Power................................................................................................................................................................ 23
B/ Internal Calibration ................................................................................................................................................... 23
Computing Internal Calibration Results .................................................................................................................. 23
C/ Reading the ADC Result Registers.......................................................................................................................... 25
RXPOT.......................................................................................................................................................................... 25
Laser Diode Bias Control.............................................................................................................................................. 25
Laser Modulation Control.............................................................................................................................................. 26
Power On and Laser Start-Up ...................................................................................................................................... 27
Fault Comparators ........................................................................................................................................................ 28
SHDN and TXFIN ......................................................................................................................................................... 29
Temperature Measurement .......................................................................................................................................... 30
Diode Faults.................................................................................................................................................................. 30
Temperature Compensation ......................................................................................................................................... 30
Alarms and Warning Flags ........................................................................................................................................... 32
Control and Status I/O .................................................................................................................................................. 32
System Timing................................................................................................................................................................. 34
Warm Resets ................................................................................................................................................................ 36
Power-On Hour Meter................................................................................................................................................... 36
Test and Calibration Features ...................................................................................................................................... 37
Serial Port Operation .................................................................................................................................................... 38
Block Writes .................................................................................................................................................................. 38
Acknowledge Polling..................................................................................................................................................... 39
Write Protection and Data Security .............................................................................................................................. 39
OEM Password....................................................................................................................................................... 39
OEM Mode and User Mode .................................................................................................................................... 39
Detailed Register Descriptions ...................................................................................................................................... 40
Alarm Threshold Registers ............................................................................................................................................ 40
Temperature High Alarm Threshold ............................................................................................................................. 40
Temperature Low Alarm Threshold .............................................................................................................................. 40
Voltage High Alarm Threshold...................................................................................................................................... 40
D[7] read/write ................................................................................................................................................................... 40
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MIC3003GFL
D[6] read/write ................................................................................................................................................................... 40
Voltage Low Alarm Threshold....................................................................................................................................... 41
Bias Current High Alarm Threshold.............................................................................................................................. 41
Bias Current Low Alarm Threshold............................................................................................................................... 41
TX Optical Power High Alarm Threshold...................................................................................................................... 41
TX Optical Power Low Alarm Threshold....................................................................................................................... 42
RX Optical Power High Alarm Threshold ..................................................................................................................... 42
RX Optical Power Low Alarm Threshold ...................................................................................................................... 42
Warning Threshold Registers ........................................................................................................................................ 43
Temperature High Warning Threshold ......................................................................................................................... 43
Temperature Low Warning Threshold .......................................................................................................................... 43
Voltage High Warning Threshold.................................................................................................................................. 43
Voltage Low Warning Threshold................................................................................................................................... 44
Bias Current High Warning Threshold.......................................................................................................................... 44
Bias Current Low Warning Threshold........................................................................................................................... 44
TX Optical Power High Warning ................................................................................................................................... 44
TX Optical Power Low Warning.................................................................................................................................... 45
RX Optical Power High Warning Threshold ................................................................................................................. 45
RX Optical Power Low Warning Threshold .................................................................................................................. 45
Checksum (CHKSUM) Checksum of bytes 0 - 94 at serial address A2h..................................................................... 45
ADC Result Registers ..................................................................................................................................................... 46
Temperature Result ...................................................................................................................................................... 46
Voltage.......................................................................................................................................................................... 46
Laser Diode Bias Current ............................................................................................................................................. 46
Transmitted Optical Power ........................................................................................................................................... 47
Received Optical Power ............................................................................................................................................... 47
Control and Status (CNTRL)......................................................................................................................................... 47
Application Select Control Mode (ASCM)..................................................................................................................... 48
Alarm Flags...................................................................................................................................................................... 50
Alarm Status Register 0 (ALARM0).............................................................................................................................. 50
Alarm Status Register 1 (ALARM1).............................................................................................................................. 50
Warning Flags.................................................................................................................................................................. 51
Warning Status Register 0 (WARN0) ........................................................................................................................... 51
Warning Status Register 1 (WARN1) ........................................................................................................................... 51
Extended Control and Status (ECNTRL)...................................................................................................................... 52
OEM Password Entry (OEMPW) .................................................................................................................................. 52
Power-On Hours (POHh and POHl) ............................................................................................................................. 53
Data Ready Flags (DATARDY) .................................................................................................................................... 53
User Control Register (USRCTL) ................................................................................................................................. 54
RESETOUT .................................................................................................................................................................. 54
OEM Configuration Register 0 (OEMCFG0) ................................................................................................................ 55
OEM Configuration Register 1 (OEMCFG1) ................................................................................................................ 56
OEM Configuration Register 2 (OEMCFG2) ................................................................................................................ 57
APC Setpoint 0, 1, and 2 (APCSET0, APCSET1, APCSET2) Automatic Power Control Setpoint.............................. 58
Modulation Setpoint 0, 1, and 2 (MODSET0, MODSET1, and MODSET2) Nominal VMOD Setpoint ........................... 58
IBIAS Fault Threshold (IBFLT) Bias Current Fault Threshold......................................................................................... 59
Transmit Power Fault Threshold (TXFLT) .................................................................................................................... 59
Loss-Of-Signal Threshold (LOSFLT)............................................................................................................................ 59
Fault Suppression Timer (FLTTMR) Fault Suppression Interval in Increments of 0.5 ms ........................................... 60
Fault Mask (FLTMSK)................................................................................................................................................... 60
OEM Password Setting (OEMPWSET) ........................................................................................................................ 61
OEM Calibration 0 (OEMCAL0).................................................................................................................................... 61
OEM Calibration 1 (OEMCAL1).................................................................................................................................... 63
LUT Index (LUTINDX) .................................................................................................................................................. 64
OEM Configuration 3 (OEMCFG3)............................................................................................................................... 64
BIAS DAC Setting (APCDAC) Current VBIAS Setting ................................................................................................. 65
Modulation DAC Setting (MODDAC) Current VMOD Setting....................................................................................... 66
OEM Readback Register (OEMRD) ............................................................................................................................. 66
July 2010
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MIC3003GFL
Signal Detect Threshold (LOSFLTn) ............................................................................................................................ 67
RX EEPOT Tap Selection (RXPOT)............................................................................................................................. 67
OEM Configuration 4 (OEMCFG4)............................................................................................................................... 67
OEM Configuration 5 (OEMCFG5)............................................................................................................................... 68
OEM Configuration 6 (OEMCFG6)............................................................................................................................... 69
Power-On Hour Meter Data (POHDATA) ..................................................................................................................... 70
OEM Scratchpad Registers (SCRATCHn) ................................................................................................................... 71
RX Power Coefficient Look-up Table (RXLUTn) .......................................................................................................... 71
Calibration Constants (CALCOEFn)............................................................................................................................. 72
Manufacturer ID Register (MFG_ID) Identifies Micrel as the manufacturer of the device. Always returns 2Ah .......... 72
Device ID Register (DEV_ID) ....................................................................................................................................... 73
Package Information....................................................................................................................................................... 74
July 2010
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MIC3003GFL
List of Figures
Figure 1. MIC3003 Block Diagram .................................................................................................................................... 18
Figure 2. Analog-to-Digital Converter Block Diagram ....................................................................................................... 18
Figure 3. Internal Calibration RX Power Linear Approximation ........................................................................................ 25
Figure 4. RXPOT Block Diagram ...................................................................................................................................... 25
Figure 5. APC and Modulation Control Block Diagram.................................................................................................... 26
Figure 6. Programmable Feedback Resistor .................................................................................................................... 26
Figure 7. Transmitter Configurations Supported by MIC3003 ......................................................................................... 26
Figure 8. VMOD Configured as Voltage Output with Gain ................................................................................................. 27
Figure 9. MIC3003 Power-On Timing (OE = 1) ................................................................................................................ 28
Figure 10. Fault Comparator Logic ................................................................................................................................... 28
Figure 11. Saturation Detector .......................................................................................................................................... 29
Figure 12. RXLOS Comparator Logic ............................................................................................................................... 29
Figure 14. Transmitter On-Off Timing .............................................................................................................................. 34
Figure 15. Initialization Timing with TXDISABLE Asserted.............................................................................................. 34
Figure 16. Initialization Timing with TXDISABLE Not Asserted ...................................................................................... 34
Figure 17. Loss-of-Signal (LOS) Timing .......................................................................................................................... 35
Figure 19. Successfully Clearing a Fault Condition ......................................................................................................... 36
Figure 20. Unsuccessful Attempt to Clear a Fault ........................................................................................................... 36
Figure 21. Write Byte Protocol ......................................................................................................................................... 38
Figure 22. Read Byte Protocol ......................................................................................................................................... 38
Figure 23. Read_Word Protocol....................................................................................................................................... 38
Figure 24. Eight-Byte Block Write Protocol...................................................................................................................... 39
July 2010
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MIC3003GFL
List of Tables
Table 1. Serial Interface Address Map, Device Address = A0h ........................................................................................ 15
Table 2. Serial Interface Address Map, Device Address = A2.......................................................................................... 15
Table 3. Serial Interface Address Map (Temperature Compensation Tables), Device Address = A4h ............................ 16
Table 4. Serial Interface Address Map (OEM Configuration Registers), Device Address = A6h ...................................... 17
Table 5. A/D Input Signal Ranges and Resolutions.......................................................................................................... 19
Table 6. VAUX Input Signal Ranges and Resolutions ........................................................................................................ 19
Table 7. Alarms Interrupt Sources Masking Bits............................................................................................................... 20
Table 8. Warnings Interrupt Sources Masking Bits........................................................................................................... 20
Table 9. RESETOUT Clear Delay..................................................................................................................................... 21
Table 10. LSB Values of Offset Coefficients..................................................................................................................... 23
Table 11. Internal Calibration Coefficient Memory Map – Part I ....................................................................................... 24
Table 12. Internal Calibration Coefficient Memory Map – Part II ...................................................................................... 24
Table 13. Shutdown State of SHDN vs. Configuration Bits ............................................................................................. 27
Table 14. Shutdown State of VBIAS vs. Configuration Bits................................................................................................ 27
Table 15. Shutdown State of VMOD vs. Configuration Bits................................................................................................ 27
Table 16. Temperature Compensation Look-up Tables ................................................................................................... 30
Table 17. APC Temperature Compensation Look-Up Table ........................................................................................... 31
Table 18. IMOD Temperature Compensation Look-Up Table ............................................................................................ 31
Table 19. IBIAS Comparator Temperature Compensation Look-Up Table ......................................................................... 31
Table 20. BIAS Current High Alarm Temperature Compensation Table .......................................................................... 31
Table 21. MIC3003 Alarm and Warning Events................................................................................................................ 33
Table 22. Test and Diagnostic Features .......................................................................................................................... 37
July 2010
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Micrel, Inc.
MIC3003GFL
Pin Configuration
24-Pin MLF® (ML)
Pin Description (MIC3003GFL only)
Pin Number
Pin Name
Pin Function
1
VDDD
Power supply input for digital functions.
2
QGPO
Open-drain output. Can be selected (via OEMCFG3 bit 7) to be an open-drain GPO or an activelow, open-drain, pulsed reset signal output controlled by the status of bits [0-2] of byte A2h: FFh.
3
GNDD
Ground return for digital functions.
4
RS0
5
VIN/INT
Digital input. Receiver Rate Select input. OR’ed with soft rate select bit SRS0 to determine the
state of the RRSOUT pin. The state of this pin is always reflected in the RS0S bit.
If bit 4 (IE) in the USRCTL register is set to 0 (its default value), this pin is configured as an analog
input. If IE bit is set to 1, this pin is configured as an open-drain output.
Analog input: Multiplexed A/D input for monitoring supply voltage, with a 0V to 5.5V input range.
Open-drain output: outputs the internally generated active-low interrupt signal /INT.
6
CLK
7
DATA
8
TXDISABLE
9
TXFAULT
10
RS1
Digital Input; Transmitter Rate Select Input; OR’ed with soft rate select bit SRS1 to determine the
state of the TRSOUT pin. The state of this pin is always reflected in the RS1S bit.
11
VRX
Analog Input. Multiplexed A/D converter input for monitoring received optical power. The input
range is 0 to VREF. A 5-bit programmable EEPOT on this pin provides coarse calibration and
ranging of the RX power measurement.
July 2010
Digital input. Serial clock input.
Digital I/O, open-drain, bi-directional serial data input/output.
Digital input; Active high. The transmitter is disabled when this input is high or the STXDIS bit is
set to 1. The state of this input is always reflected in the TXDIS bit.
Digital Output; Open-Drain, with programmable polarity. If OEMCFG5 bit 4 is set to 0, a high level
indicates a hardware fault impeding transmitter operation. If OEMCFG5 bit 4 is set to 1, a low level
indicates a hardware fault impeding transmitter operation. The state of this pin is always reflected
in the TXFLT bit.
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MIC3003GFL
Pin Number
Pin Name
Pin Function
12
SHDN/TXFIN
13
VILD+
Analog Input. Multiplexed A/D input for monitoring laser bias current via a sense resistor (signal
input); accommodates inputs referenced to VDD or GND (see pin 14 description).
14
VILD–
Analog Input. Reference terminal for the multiplexed pseudo-differential A/D converter inputs for
monitoring laser bias current via a sense resistor (VILD+ is the sensing input). Tie to VDD or GND
to reference the voltage sensed on VILD+ to VDD or GND, respectively.
Digital output/Input; programmable polarity. When used as shutdown output (SHDN), OEMCFG3
bit 2 set to 0, SHDN is asserted at the detection of a fault condition if OEMCFG4 bit 7 is set to 0. If
OEMCFG4 bit 7 is set to 1, a fault condition will not assert SHDN. When programmed as TXFIN, it
is an input for external fault signals to be OR’ed with the internal fault sources to drive TXFAULT.
15
VDDA
Power supply input for analog functions.
16
GNDA
Ground return for analog functions.
17
VMPD
Analog Input. Multiplexed A/D converter input for monitoring transmitted optical power via a
monitor photodiode. In most applications, VMPD will be connected directly to FB. The input range
is 0 - VREF or 0 - VREF/4 depending upon the setting of the APC configuration bits
18
FB
19
VMOD
Analog Output. Buffered DAC output to set the modulation current on the laser driver IC. Operates
with either a 0– VREF or a (VDD–VREF) – VDD output swing so as to generate either a groundreferenced or a VDD referenced programmed voltage. A simple external circuit can be used to
generate a programmable current for those drivers that require a current rather than a voltage
input.
20
VMOD–
Analog input. This pin is the inverting terminal of the VMOD buffer op-amp. Connect to VMOD
(gain = 1) or a feedback resistor network to set a different gain value.
21
VBIAS
Analog output. Buffered DAC output capable of sourcing or sinking up to 10mA under control of
the APC function to drive an external transistor or the APCSET pin of a laser diode driver for laser
diode DC bias. The output and feedback polarity are programmable to accommodate either an
NPN or a PNP transistor to drive a common-anode or common-cathode laser diode.
22
COMP
Analog output. Compensation terminal for the APC loop. Connect a capacitor between this pin and
GNDA or VDDA with the appropriate value to tune the APC loop time constant to a desirable value.
23
RRSOUT/
GPO
Analog Input. Feedback voltage for the APC loop op-amp. Polarity and scale are programmable
via the APC configuration bits I OEMCFG1. Connect to VBIAS if APC is not used.
Digital Output. Open-Drain or push-pull.
If OEMCFG3 bit 4 is set to 0, RRSOUT is selected. It represents the receiver rate select as per
SFF. This output is controlled by the SRS0 bit OR’ed with RS0 input and is open drain only.
If OEMCFG3 bit 4 is set to 1, GPO is selected. General-purpose, non-volatile output, it is
controlled by the GPO configuration bits in OEMCFG3.
24
RXLOS/
TRSOUT
Digital output. This programmable polarity, open-drain outputs has two purposes:
If OEMCFG6 bit 2 = 0, indicates the loss of the received signal as indicated by a level of received
optical power below the programmed RXLOS comparator threshold; may be wire-OR’ed with
external signals. Normal operation is indicated by a low level when OEMCFG6 bit 3 is set to 0 and
a high level when OEMCFG6 bit 3 is set to 1. RXLOS is de-asserted when VRX > LOSFLTn. The
LOS bit reflects the state of RXLOS whether driven by the MIC3003 or an external circuit.
If OEMCFG6 bit 2 = 1, TRSOUT is selected. This signal represents the transmitter rate select as
per the SFF specification. This output is controlled by the SRS1 bit OR’ed with the RS1 input.
July 2010
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MIC3003GFL
Absolute Maximum Ratings(1)
Operating Ratings(2)
Power Supply Voltage, VDD ....................................... +3.8V
Voltage on CLK, DATA, TXFAULT, VIN, RXLOS,
TXDISABLE, RS0, RS1 ......................... –0.3V to +6.0V
Voltage On Any Other Pin.....................–0.3V to VDD+0.3V
Power Dissipation, TA = 85°C .................................... 1.5W
Junction Temperature (TJ) ....................................... 150°C
Storage Temperature (TS)....................... –65°C to +150°C
Soldering (20 sec.) ................................................... 260ºC
ESD Ratings(3)
Human Body Model.................................................. 2kV
Machine Model ....................................................... 300V
Power Supply Voltage, VDDA/VDDD ........... +3.0V to +3.6V
Ambient Temperature Range (TA) .......–40°C to +105°C
Package Thermal Resistance
MLF® (θJA) .................................................60°C/W
Electrical Characteristics
For typical values, TA = 25°C, VDDA = VDDD = +3.3V, unless otherwise noted. Bold values are guaranteed for +3.0V ≤ (VDDA = VDDD)
(8)
≤ 3.6V, T(min) ≤ TA ≤ T(min),
Symbol
Parameter
Condition
Min
Typ
Max
Units
CLK = DATA = VDDD = VDDA; TXDISABLE
low; all DACs at full-scale; all A/D inputs
at full-scale; all other pins open.
2.3
3.5
mA
CLK = DATA = VDDD = VDDA; TXDISABLE
high; FLTDAC at full-scale; all A/D inputs
at full-scale; all other pins open.
2.3
3.5
mA
2.9
2.98
V
Power Supply
IDD
Supply Current
VPOR
Power-on Reset Voltage
All registers reset to default values;
A/D conversions initiated.
VUVLO
Under-Voltage Lockout Threshold
Note 5
VHYST
Power-on Reset Hysteresis Voltage
tPOR
Power-on Reset Time
VREF
Reference Voltage
ΔVREF/
ΔVDDA
Voltage Reference Line Regulation
2.5
VDD > VPOR, Note 4
1.210
2.73
V
170
mV
50
µs
1.225
1.240
1.7
V
mV/V
Temperature-to-Digital Converter Characteristics
Local Temperature Measurement
Error
–40°C ≤ TA ≤ +105°C, Note 6
tCONV
Conversion Time
Note 4
tSAMPLE
Sample Period
±1
±3
°C
60
ms
100
ms
Voltage-to-Digital Converter Characteristics (VRX, VAUX, VBIAS, VMPD, VILD±)
Voltage Measurement Error
–40°C ≤ TA ≤ +105°C, Note 6
±2.0
%fs
tCONV
Conversion Time
Note 4
±1
10
ms
tSAMPLE
Sample Period
Note 4
100
ms
Notes:
1. Exceeding the absolute maximum rating may damage the device.
2. The device is not guaranteed to function outside its operating rating.
3. Devices are ESD sensitive. Handling precautions recommended. Human body model, 1.5k in series with 100pF.
4. Guaranteed by design and/or testing of related parameters. Not 100% tested in production.
5. The MIC3003 will attempt to enter its shutdown state when VDD falls below VUVLO. This operation requires time to complete. If the supply voltage falls
too rapidly, the operation may not be completed.
6. Does not include quantization error.
July 2010
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MIC3003GFL
Voltage Input, VIN (Pin 5 used as an ADC Input)
Symbol
Parameter
Condition
VIN
Input Voltage Range
–0.3 V ≤ VDD ≤ 3.6V
Min
ILEAK
Input Current
VIN = VDD or GND; VAUX = VIN
CIN
Input Capacitance
Typ
GNDA
Max
Units
5.5
V
55
µA
10
pF
Digital-to-Voltage Converter Characteristics (VMOD, VBIAS)
Accuracy
–40°C ≤ TA ≤ +105°C, Note 7
tCONV
Conversion Time
Note 8
DNL
Differential Non-linearity Error
Note 8
±1
±0.5
2.0
%fs
20
ms
±1
LSB
VREF/4
mV
±1
µA
Bias Current Sense Inputs, VILD+, VILD–
VILD
Differential Input Signal Range,
| VILD+ – VILD– |
IIN+
VILD+ input current
IIN–
VILD– input current
|
CIN
VILD+ –
VILD–
| = 0.3V
0
VILD– referred to VDDA
+150
µA
VILD–
-150
µA
10
pF
1
MHz
1
µV/°C
referred to GND
Input Capacitance
APC Op Amp, FB, VBIAS, COMP
GBW
Gain Bandwidth Product
TCVOS
Input Offset Voltage Temperature
Coefficient(4)
VOUT
Output Voltage Swing
CCOMP = 20pF; Gain = 1
IOUT = 10mA, SRCE bit = 1
GNDA
1.25
V
IOUT = -10mA, SRCE bit = 0
VDDA -1.25
VDDA
V
ISC
Output Short-Circuit Current
tSC
Short Circuit Withstand Time
TJ ≤ 150°C, Note 8
PSRR
Power Supply Rejection Ratio
CCOMP = 20pF; gain = 1, to GND
55
CCOMP = 20pF; gain = 1, to VDD
40
55
AMIN
Minimum Stable Gain
CCOMP = 20pF, note 8
ΔV/Δt
Slew Rate
CCOMP = 20pF; gain = 1
ΔRFB
mA
sec
dB
1
V/V
3
V/µs
Internal Feedback Resistor
Tolerance
±20
%
ΔRFB/Δt
Internal Feedback Resistor
Temperature Coefficient
25
ppm/C
ISTART
Laser Start-up Current Magnitude
START = 01h
0.375
mA
START = 02h
0.750
mA
START = 04h
1.500
mA
START = 08h
3.000
mA
10
pF
CIN
Pin Capacitance
Notes:
7. Does not include quantization error.
8. Guaranteed by design and/or testing of related parameters. Not 100% tested in production.
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MIC3003GFL
Electrical Characteristics
Symbol
Parameter
Condition
Min
Typ
Max
Units
VMOD Buffer Op-Amp, VMOD, VMOD–
GBW
Gain Bandwidth
TCVOS
IBIAS
Input Offset Voltage Temperature
Coefficient
VMOD– Input Current
VOUT
Output Voltage Swing
ISC
Output Short-Circuit Current
CCOMP = 20pF; gain = 1
1
MHz
1
µV/°C
±0.1
IOUT = ±1mA
GNDA+75
±1
µA
VDDA-75
mV
35
mA
tSC
Short Circuit Withstand Time
TJ ≤ 150°C, Note 9
PSRR
Power Supply Rejection Ratio
CCOMP = 20pF; gain = 1, to GND
65
dB
CCOMP = 20pF; gain = 1, to VDD
44
dB
AMIN
Minimum Stable Gain
CCOMP = 20pF
ΔV/ΔT
Slew Rate
CCOMP = 20pF; gain = 1
CIN
Pin Capacitance
sec
1
V/V
1
V/µs
10
pF
Control and Status I/O, TXDISABLE, TXFAULT, RS0, RRSOUT(GPO), SHDN(TXFIN), RXLOS(TRSOUT), /INT, RS1, QGPO
VIL
Low Input Voltage
VIH
High Input Voltage
VOL
Low Output Voltage
IOL ≤ 3mA
0.3
V
VOH
IOH ≤ 3mA
VDDD–0.3
V
ILEAK
High Output Voltage
(applies to SHDN only)
Input Current
±1
µA
CIN
Input Capacitance
0.8
2.0
V
V
10
pF
Transmit Optical Power Input, VMPD
VIN
Input Voltage Range
Note 9
VRX
Input Signal Range
BIASREF=0
CIN
Input Capacitance
Note 9
ILEAK
Input Current
GNDA
VDDA–VREF
BIASREF=1
VDDA
V
VREF
V
VDDA
10
V
pF
±1
µA
GNDA
VDDA
V
0
VREF
V
Received Optical Power Input, VRX, RXPOT
Input Voltage Range
VRX
Note 9
RRXPOT(32)
Valid Input Signal Range
(ADC Input Range)
End-to-End Resistance
ΔRXPOT
Resistor Tolerance
ΔRXPOT/ΔT
Resistor Temperature Coefficient
ΔVRX/VRXPOT
Divider Ratio Accuracy
00 ≤ RXPOT ≤ 1Fh
ILEAK
Input Current
RXPOT = 0 (disconnected)
CIN
Input Capacitance
Note 9
ILEAK
Input Current
RXPOT = 1Fh
32
KΩ
±20
%
25
-5
ppm/ºC
+5
%
±1
µA
10
pF
±1
µA
Note:
9. Guaranteed by design and/or testing of related parameters. Not 100% tested in production.
July 2010
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MIC3003GFL
Electrical Characteristics
Symbol
Parameter
Condition
Min
Typ
Max
Units
Control and Status I/O Timing, TXFAULT, TXDISABLE, RS0, RRSOUT, and RXLOS
tOFF
TXDISABLE Assert Time
From input asserted to optical output
at 10% of nominal, CCOMP = 10nF.
10
µs
tON
TXDISABLE De-assert Time
From input de-asserted to optical output
at 90% of nominal, CCOMP = 10nF.
1
ms
tINIT
Initialization Time
From power on or transmitter enabled to
optical output at 90% of nominal and
TX_FAULT de-asserted. Note 10.
300
ms
tINIT2
Power-on Initialization Time
From power on to APC loop-enabled.
200
ms
tFAULT
TXFAULT Assert Time
From fault condition to TXFAULT
assertion. Note 10.
95
µs
tRESET
Fault Reset Time
Length of time TXDISABLE must be
asserted to reset fault condition.
tLOSS_ON
RXLOS Assert Time
From loss of signal to RXLOS asserted.
95
µs
tLOSS_OFF
RXLOS De-assert Time
From signal acquisition to LOS
de-asserted.
100
µs
tDATA
Analog Parameter Data Ready
From power on to valid analog
parameter data available. Note 10
400
ms
tPROP_IN
TXFAULT, TXDISABLE, RXLOS,
RS0, RS1 Input Propagation Time
Time from input change to
corresponding internal register bit set or
cleared. Note 10.
1
µs
tPROP_OUT
TXFAULT, TRSOUT, TRRSOUT,
/INT, QGPO Output Propagation
Time
From an internal register bit set or
cleared to corresponding output change.
Note 10.
1
µs
0.525
ms
+3
%/fs
µs
10
Fault Comparators
FLTTMR
Fault Suppression Timer Clock
Period
tREJECT
Glitch Rejection
Maximum length pulse that will not
cause output to change state. Note 10.
VSAT
Saturation Detection Threshold
High level
95
%VDDA
Low level
5
%VDDA
Note 10.
0.475
Accuracy
0.5
-3
4.5
µs
Power-On Hour Meter
Timebase Accuracy
Resolution
0°C ≤ TA ≤ +70°, Note 10.
+5
-5
%
–40°C ≤ TA ≤ +105°C
+10
-10
%
Note 10.
10
hours
Non-Volatile (FLASH) Memory
tWR
Write Cycle Time, Note 11
Measured from the SMBus STOP
condition of a one-byte to eight-byte
write transaction. Note 10.
NVRAM Data Retention
Endurance
Maximum permitted number of write
cycles to any single NVRAM location
ms
13
100
years
10,000
cycles
Notes:
10. Guaranteed by design and/or testing of related parameters. Not 100% tested in production.
11. The MIC3003 will not respond to serial bus transactions during an EEPROM write cycle. The host will receive a NACK response during tWR.
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MIC3003GFL
Serial Data I/O Pin, Data
Symbol
Parameter
Condition
Max
Units
VOL
Low Output Voltage
IOL = 3mA
0.4
V
IOL = 6mA
0.6
V
0.8
V
VIL
Low Input Voltage
VIH
High Input Voltage
ILEAK
Input Current
CIN
Input Capacitance
Min
Typ
V
2.1
±1
Note 12
10
µA
pF
Serial Clock Input, CLK
VIL
Low Input Voltage
2.7V ≤ VDD ≤ 3.6V
VIH
High Input Voltage
2.7V ≤ VDD ≤ 3.6V
ILEAK
Input Current
CIN
Input Capacitance
Serial Interface Timing
0.8
V
2.1
±1
Note 12
V
10
µA
pF
(4)
t1
CLK (clock) Period
2.5
µs
t2
Data In Setup Time to CLK High
100
ns
t3
Data Out Stable After CLK Low
300
ns
t4
Data Low Setup Time to CLK Low
Start Condition
100
ns
t5
Data High Hold Time After CLK High
Stop Condition
100
ns
tDATA
Data Ready Time
From power on to completion of one set
of ADC conversions; analog data
available via serial interface.
400
ms
QGPO Reset Pulse Timing
t1
QGPO reset pulse low duration
OEMCFG3 bit 7 = 1
A2h:255 (FFh) [2-0] switch to 111
112.5
125
137.5
µs
t2
QGPO reset de-assertion to the
clearing of A2:FFh bits 2:0
OEMCFG3 bit 7 = 1
A2h:255 (FFh) [2-0] ≠ 111
20.25
22.5
24.75
ms
Note:
12. Guaranteed by design and/or testing of related parameters. Not 100% tested in production.
Serial Interface Timing Diagram
Serial Interface Timing
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MIC3003GFL
Serial Interface Address Maps
Address
(Decimal)
Field Size
(Bytes)
Name
Description
0 –95
96
Serial ID defined by SFP MSA
General-purpose NVRAM; R/W under valid OEM password.
96 – 127
32
Vendor Specific
Vendor specific EEPROM
128 – 255
128
Reserved
Reserved for future use. General-purpose NVRAM; R/W under
valid OEM password.
Table 1. Serial Interface Address Map, Device Address = A0h
Hex
Dec
Field Size
(Bytes)
Name
Description
00-27
0-39
40
Alarm and Warning Thresholds
High/low limits for warnings and alarms; writeable using the
OEM password; read-only otherwise.
28-37
40-55
16
Reserved
Reserved – do not write; reads undefined.
38-5B
56-91
36
Calibration Constants
Numerical constants for external calibration; writeable using
the OEM password; read-only otherwise.
5C-5E
92-94
3
Reserved
Reserved – do not write; reads undefined.
5F
95
1
Checksum
General-purpose NVRAM; writeable using the OEM password;
read-only otherwise.
60-69
96-105
10
Analog Data
Real time analog parameter data.
6A-6D
106-109
4
Reserved
Reserved – do not write; reads undefined.
6E
110
1
Control/Status Register
Control and status bits.
6F
111
1
Rate Select Control
Bits [7-6] control the use of the RS0 and RS1 inputs and the
SRS0 and SRS1 register bits.
70-71
112-113
2
Alarm Flags
Alarm status bits; read-only.
72-73
114-115
2
Reserved
Reserved – do not write; reads undefined.
74-75
116-117
2
Warning Flags
Warning status bits; read-only.
76
118
1
Extended Control/Status
Register
Additional control and status bits.
77
119
1
Reserved
Reserved – do not write; reads undefined.
78-7E
120-126
7
OEMPW
OEM password entry field. The four-byte OEM password
location can be selected to be 78h-7Bh (120-123) by setting
OEMCFG5 bit 2 to 0 (default) or 7Bh-7Eh (123-126) by setting
OEMCFG5 bit 2 to a one.
Address(s)
7F
127
1
Vendor-specific
Vendor specific. Reserved – do not write; reads undefined.
80-F7
128-247
120
User Scratchpad
User-writeable EEPROM. General-purpose NVRAM.
F8-F9
248-249
2
Alarms Masks
Bit = 0: Corresponding alarm not masked.
Bit = 1: Corresponding alarm masked.
FA-FB
250-251
2
Warnings Masks
Bit = 0: Corresponding warning not masked.
Bit = 1: Corresponding warning masked.
FC-FD
252-253
2
Reserved
Reserved – do not write; reads undefined.
FE
254
1
USRCTL
End-user control and status bits.
FF
255
1
RESETOUT
Bits [2:0] of this register control the QGPO reset output (pin 2)
If OEMCFG3 bit 7 is set to 1.
Table 2. Serial Interface Address Map, Device Address = A2
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MIC3003GFL
Address(s)
Hex
Dec
00-3F
0-63
40-7F
Field Size
(Bytes)
Name
Description
64
BIASLUT1
First 64 entries of the bias current temperature compensation LUT (Lookup Table) The additional 12 entries are located in A6: 58h – 63h.
64-127
64
MODLUT1
First 64 entries of the modulation current temperature compensation
LUT. The additional 12 entries are located in A6:.64h – 6Fh.
80-BF
128-191
64
IFTLUT1
First 64 entries of the bias current fault threshold temperature
compensation LUT. The additional 12 entries are located in A6: 70h 7Bh.
C0-FF
192-255
64
HATLUT1
First 64 entries of the bias current high alarm threshold temperature
compensation LUT. The additional 12 entries are located in A6: 7C-87h.
Table 3. Serial Interface Address Map (Temperature Compensation Tables), Device Address = A4h
Hex
Dec
Field Size
(Bytes)
00
0
1
OEMCFG0
OEM configuration register 0
01
1
1
OEMCFG1
OEM configuration register 1
02
2
1
OEMCFG2
OEM configuration register 2
03
3
1
APCSET0
APC setpoint register 0
04
4
1
APCSET1
APC setpoint register 1
05
5
1
APCSET2
APC setpoint register 2
06
6
1
MODSET0
Modulation setpoint register 0
07
7
1
IBFLT
Bias current fault-comparator threshold. This register is temperature
compensated.
08
8
1
TXPFLT
TX power fault threshold
Address(s)
Name
Description
09
9
1
LOSFLT
RX LOS fault-comparator threshold
0A
10
1
FLTTMR
Fault comparator timer setting
0B
11
1
FLTMSK
Fault source mask bits
0C-0F
12-15
4
OEMPWSET
Password for access to OEM areas
10
16
1
OEMCAL0
OEM calibration register 0
11
17
1
OEMCAL1
OEM calibration register 1
12
18
1
LUTINDX
Look-up table index read-back
13
19
1
OEMCFG3
OEM configuration register 3
14
20
1
APCDAC
Reads back current APC DAC value (setpoint+offset)
15
21
1
MODDAC
Reads back current modulation DAC value (setpoint+offset)
16
22
1
OEMREAD
Reads back OEM calibration data
17
23
1
LOSFLTn
LOS de-assert threshold
18
24
1
RXPOT
RXPOT tap selection
19
25
1
OEMCFG4
OEM configuration register 4
1A
26
1
OEMCFG5
OEM configuration register 5
1B
27
1
OEMCFG6
OEM configuration register 6
1C-1D
28-29
2
SCRATCH
Reserved – do not write; reads undefined.
1E
30
1
MODSET 1
Modulation setpoint register 1
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MIC3003GFL
Address(s)
HEX
Field Size
(Bytes)
DEC
Name
Description
1F
31
1
MODSET 2
Modulation setpoint register 2
20-27
32-39
8
POHDATA
Power-on hour meter scratchpad
28-47
40-71
32
RXLUT
RX power internal calibration coefficient table. Eight sets of slope and
offset coefficients provide a piecewise-linear transform for the receive
power ADC result.
48-57
72-87
16
CALCOEF
Slope and offset coefficients used for temperature, voltage, bias current,
and transmit power internal calibration
58-63
88-99
12
IFTLUT2
Additional 12 entries of the bias current fault threshold temperature
compensation LUT.
64-6F
100-111
12
BIASLUT2
Additional 12 entries of the bias current temperature compensation LUT.
70-7B
112-123
12
MODLUT2
Additional 12 entries of the modulation current temperature
compensation LUT.
7C-87
124-135
12
HATLUT2
Additional 12 entries of the bias current high alarm threshold
temperature compensation LUT.
88-CF
136-207
72
SCRATCH
OEM scratchpad area
D0-DD
208-221
14
RXLUTSEG/
SCRATCH
Receive power calibration segment delimiters. Each of the eight
segments can have its own slope and offset coefficient. Used to refine
the shape of the piecewise-linear function used for receive power in
internal calibration mode.
These bytes may also be part of the OEM scratch pad if the hard coded
delimiters option is selected, see the description of OEMCFG6
DE-FA
222-250
29
SCRATCH
OEM scratchpad area
FB-FC
251-252
2
POH
Power on hour meter result; read-only
FD
253
1
Data Ready Flags
Data ready bits for each measured parameter; read-only
FE
254
1
MFG_ID
Manufacturer identification (Micrel’s manufacturer ID is 42, 2Ah)
FF
255
1
DEV_ID
Device ID and die revision
Table 4. Serial Interface Address Map (OEM Configuration Registers), Device Address = A6h
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MIC3003GFL
Block Diagram
Figure 1. MIC3003 Block Diagram
Analog-to-Digital Converter/Signal
Monitoring
A block diagram of the monitoring circuit is shown below.
Each of the five analog parameters monitored by the
MIC3003 is sampled in sequence. All five parameters are
sampled and the results updated within the tCONV duration
given in the “Electrical Characteristics” section. In OEM
mode, the channel that is normally used to measure VIN
may be assigned to measure the level of the VDDA pin or
one of five other nodes. This provides a kind of analog
loopback for debug and test purposes. The VAUX bits in
OEMCFG0 control which voltage source is being
sampled. The various VAUX channels are level-shifted
differently depending on the signal source, resulting in
different LSB values and signal ranges. See Table 5.
July 2010
Figure 2. Analog-to-Digital Converter Block Diagram
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MIC3003GFL
Channel
ADC Resolution
(bits)
TEMP
8 or 9
VAUX
8
VMPD
8
VILD
8
VRX
12
Conditions
Input Range (V)
LSB(1)
N/A
1°C or 0.5°C
See Table 6
GAIN = 0; BIASREF = 0
GNDA - VREF
GAIN = 0; BIASREF = 1
VDDA – (VDDA – VREF)
GAIN = 1; BIASREF = 0
GNDA - VREF/4
GAIN = 1; BIASREF = 1
VDDA – (VDDA – VREF/4)
VILD- = VDDA
VDDA – (VDDA – VREF)
VILD- = GNDA
GNDA - VREF
RXPOT = 00
0 - VREF
4.77mV
1.17mV
4.77mV
0.298mV
Table 5. A/D Input Signal Ranges and Resolutions
Note:
1. Assumes typical VREF value of 1.22V.
Channel
VAUX [2:0]
Input Range (V)
LSB(1) (mV)
VIN
000 = 00h
0.5V to 5.5V
25.6mV
VDDA
001 = 01h
0.5V to 5.5V
25.6mV
VBIAS
010 = 02h
0.5V to 5.5V
25.6mV
VMOD
011 = 03h
0.5V to 5.5V
25.6mV
APCDAC
100 = 04h
0V to VREF
4.77mV
MODDAC
101 = 05h
0V to VREF
4.77mV
FLTDAC
110 = 06h
0V to VREF
4.77mV
Table 6. VAUX Input Signal Ranges and Resolutions
Note:
1. Assumes typical VREF value of 1.22V.
Alarms and Warnings Interrupt Source Masking
Alarm and warning violations set the flags in the Alarm
and Warning Status Registers, and also assert the
interrupt output if they are not masked. If an alarm or
July 2010
warning is masked, it will not set the interrupt. Table 8
shows the locations of the masking bits. The warning or
alarm is masked if the corresponding bit is set to 1.
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MIC3003GFL
Serial Address A2h
Byte
248
249
Bit
Default Value
Description
7
0
Masking bit for Temperature High Alarm interrupt source
6
0
Masking bit for Temperature Low Alarm interrupt source
5
0
Masking bit for Voltage High Alarm interrupt source
4
0
Masking bit for Voltage Low Alarm interrupt source
3
0
Masking bit for Bias High Alarm interrupt source
2
0
Masking bit for Bias Low Alarm interrupt source
1
0
Masking bit for TX Power High Alarm interrupt source
0
0
Masking bit for TX Power Low Alarm interrupt source
7
0
Masking bit for RX Power High Alarm interrupt source
6
1
Masking bit for RX Power Low Alarm interrupt source
[5-0]
Reserved
Table 7. Alarms Interrupt Sources Masking Bits
Serial Address A2h
Byte
250
Bit
Default Value
Description
7
0
Masking bit for Temperature High Warning interrupt
source
6
0
Masking bit for Temperature Low Warning interrupt
source
5
0
Masking bit for Voltage High Warning interrupt source
4
0
Masking bit for Voltage Low Warning interrupt source
3
0
Masking bit for Bias High Warning interrupt source
2
0
Masking bit for Bias Low Warning interrupt source
1
0
Masking bit for TX Power High Warning interrupt source
0
0
Masking bit for TX Power Low Warning interrupt source
7
0
Masking bit for RX Power High Warning interrupt source
6
1
Masking bit for RX Power Low Warning interrupt source
[5-0]
Reserved
251
Table 8. Warnings Interrupt Sources Masking Bits
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Alarms and Warnings as TXFAULT Source
Alarms and warnings are not sources for TXFAULT with
the default setting. To set alarms as a TXFAULT source
set OEMCFG4 bit 6 to 1. To set warnings as a
TXFAULT, source set OEMCFG4 bit 7 to 1. The alarms
and warnings TXFAULT sources can be masked
individually in the same way shown in Tables 7 and 8.
Latching of Alarms and Warnings
Alarms and warnings are latched by default, i.e., once
asserted the flags remain ON until the register is read or
TXDSABLE is toggled. If OEMCFG4 bit 5 is set to 1, the
warnings are not latched and will be set and reset with
the warning condition. Reading the register or toggling
TXDISABLE will clear the flag. If OEMCFG4 bit 4 is set
to 1, the alarms are not latched and will be set and reset
with the alarm condition. Reading the register or toggling
TXDISABLE will clear the flag.
MIC3003GFL
QGOP Pin Function
QGOP can be used in GOP mode as a general purpose
output by setting OEMCFG3 bit 7 to 0, or as in RESET
mode as a reset signal output by setting OEMCFG3 bit 7
to 1.
If RESET mode is selected, the reset signal state is
controlled by RSETOUT (A2:FFh bits [2-0]). By default,
these three bits are 000, and the QGPO output is
undriven (state: High). When the three bits are written to
111, QGPO’s open-drain output will be driven low for
125 μs (typical), after which QGPO reenters the undriven
state. The RESETOUT field is cleared from 111 to 000
22.5 ms (typical) after the de-assertion edge of QGPO.
Other values of this delay may be selected by setting
TRSTCLR (OEMCFG2 bits [2-0]) to different values as
shown on table.
If Reset mode in OEMCFG3 is not selected, these three
bits have no function.
SMBus Multipart Support
If more than one MIC3003GFL device shares the same
serial interface and multipart mode is selected on them
(OEMCFG5 bit 3 = 1), then pin 12 and pin 23 become
SMBus address bits 3 and 4 respectively. Therefore, the
parts should have a different setting on those pins to
create four address combinations based upon the state
of pin 12 and pin 23 state, (00, 01, 10, 11) where 0 is a
pull down to GND and 1 is a pull up to VCC. The parts
come from the factory with the same address (A0) and
multipart mode off (OEMCFG5 bit 3 is 0). After power
up, write 1 to OEMCFG5 bit 3 to turn ON multipart mode,
which is done to all parts at the same time since they all
respond to serial address A0 at this point. With multipart
mode on, the parts have now different addresses based
on the states of pins 12 and 23. Another option is to
access each part individually, set their single mode
address in OEMCFG2 bits [4-7] to different values and
then turn off multipart mode to return to normal mode
where the parts have new different addresses.
July 2010
TRSTCLR
[2-0]
Delay from QGPO
Switching high to
RESETOUT clear
000
Zero delay
001
17.5 ms typical
010
22.5 ms typical (default)
011
27 ms typical
100
45 ms typical
Table 9. RESETOUT Clear Delay
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MIC3003GFL
Calibration Modes
The default mode of calibration in the MIC3003 is
external calibration, for which the INTCAL bit (bit 0 in
OEMCFG3 register) is set to 0. The internal calibration
mode is selected by setting INTCAL to 1.
A/ External Calibration
The voltage and temperature values returned by the
MIC3003’s A/D converter are internally calibrated. The
binary values of TEMPh:TEMPl and VOLTh:VOLTl are in
the format called for by SFF-8472 under Internal
Calibration.
SFF-8472 calls for a set of calibration constants to be
stored by the transceiver OEM at specific non-volatile
memory locations; refer to the SFF-8472 specifications
for the memory map of the calibration coefficients. The
MIC3003 provides the non-volatile memory required for
the storage of these constants. The Digital Diagnostic
Monitoring Interface specification should be consulted
for full details. Slopes and offsets are stored for use with
voltage, temperature, bias current, and transmitted
power measurements. Coefficients for a fourth-order
polynomial are provided for use with received power
measurements. The host system can retrieve these
constants and use them to process the measured data.
Voltage
The voltage values returned by the MIC3003’s A/D
converter are internally calibrated. The binary values of
VOLTh:VOLTl are in the format called for by SFF-8472
under Internal Calibration. Since VINh:VINl requires no
processing, the corresponding slope should be set to
one and the offset to zero.
Temperature
The temperature values returned by the MIC3003’s A/D
converter are internally calibrated. The binary values of
TEMPh:TEMPl are in the format called for by SFF-8472
under Internal Calibration.
The temperature value may be offset by storing a value
in A6:74(4Ah). The temperature offset is a six-bit signed
quantity with .5 degrees C resolution.
The temperature offset coefficient at A6:74(4Ah) is used
in the same way in both internal and external calibration
modes.
Bias Current
Bias current is sensed via an external sense resistor as
a voltage appearing between VILD+ and VILD-. The
value returned by the A/D is therefore a voltage
analogous to bias current. Bias current, IBIAS, is simply
VVILD/RSENSE. The binary value in IBIASh (IBIASl is
always zero) is related to bias current by:
July 2010
(0.3 V )
IBIAS =
IBIASh
255
(1)
R SENSE
The value of the least significant bit (LSB) of IBIASh is
given by:
LSB(IBIASh ) =
mA =
0 .3 v
300mV
Amps =
255 × R SENSE
255 × R SENSE
1176.9
μA
R SENSE
(2)
Per SFF-8472, the value of the bias current LSB is 2µA.
The necessary conversion factor, “slope”, is therefore:
Slope =
1176.5μA
= 2.298 + R SENSE
512μA × R SENSE
The tolerance of the sense resistor directly impacts the
accuracy of the bias current measurement. It is
recommended that the sense resistor chosen be 1%
accurate or better. The offset correction, if needed, can
be determined by shutting down the laser, i.e., asserting
TXDISABLE, and measuring the bias current. Any nonzero result gives the offset required. The offset will be
equal and opposite to the result of the “zero current”
measurement.
TX Power
Transmit power is sensed via a resistor carrying the
monitor photodiode current. In most applications, the
signal at VMPD will be feedback voltage on FB. The
VMPD voltage may be measured relative to GND or
VDDA depending on the setting of the BIASREF bit in
OEMCFG1. The value returned by the A/D is therefore a
voltage analogous to transmit power. The binary value in
TXOPh (TXOPl is always zero) is related to transmit
power by:
K × VREF
PTX(mW ) =
TXOPh
255
R SENSE
K × (1220mV )
=
TXOPh
255
R SENSE
K × 4.7843 × TXOPh
mW
(3)
R SENSE
For a given implementation, the value of RSENSE is
known. It is either the value of the external resistor or the
selected internal value of RFB. The constant, K, will likely
have to be determined through experimentation or
closed-loop calibration, as it depends on the monitoring
photodiode responsively and coupling efficiency.
It should be noted that the APC circuit acts to hold the
transmitted power constant. The value of transmit power
reported by the circuit should only vary by a small
amount as long as the APC is functioning correctly.
=
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RX Power
Received power is sensed as a voltage appearing at
VRX. It is assumed that this voltage is generated by a
sense resistor carrying the receiver photodiode current
or by the RSSI circuit of the receiver. The value returned
by the A/D is therefore a voltage analogous to received
power. The binary values in RXOPh and RXOPl are
related to receive power by:
RX(mW ) = K × VREF × (256 × RXOPh + RXOPl / 16) • 65536
(4)
For a given implementation, the constant, K, will likely
have to be determined through experimentation or
closed-loop calibration, as it depends upon the gain and
efficiencies
of
the
receiver.
In
SFF-8472
implementations, the external calibration constants can
describe up to a fourth-order polynomial in case K is
nonlinear.
B/ Internal Calibration
If the INTCAL bit in OEMCFG3 is set to 1 (internal
calibration selected), the MIC3003 will process each
piece of data coming out of the A/D converter before
storing the result in result register. Linear slope/offset
correction will be applied on a per-channel basis to the
measured values for voltage, bias current, TX power,
and RX power. Only offset is applied to temperature.
The user must store the appropriate slope/offset
coefficients in memory at the time of transceiver
calibration. In the case of RX power, a look-up table is
provided that implements eight-segment piecewiselinear correction. This correction may be performed as a
compensation of the receiver non-linearity over
temperature or receive power level. If static slope/offset
correction for RX power is desired, the eight coefficient
sets can simply be made the same. The user has the
option to select between using preset hard-coded
delimiters values or programmable delimiters where
delimiters corresponding to the best linear approximation
intervals of a specific receiver can be entered. The latter
option will use an additional fourteen (14) bytes from the
OEM scratch pad A6h:208-221(DOh-DDh). OEMCFG6
bits [6:5] are used to select between these options. The
memory maps for the calibration coefficients are shown
in Tables 11 and 12. If the programmable delimiters
option is selected, the user must enter the seven
delimiters of the intervals that best fit the receiver
response. The diagram in Figure 3 shows the link
between the delimiters and the sets of slopes and
offsets.
Slopes Coefficients
The slopes allow for the correction of gain errors. Each
slope coefficient is an unsigned, sixteen-bit, fixed-point
binary number in the format:
[mmmmmmmm .llllllll]
July 2010
where m is a data bit in the most-significant byte and l is
a data bit in the least significant byte
Slopes are always positive. The decimal point is in
between the two bytes, i.e., between bits 7 and 8. This
provides a numerical range of 1/256 (0.00391) to
255.997 in steps of 1/256. The most significant byte is
always stored in memory at the lower numerical
address.
Offset coefficients
The offsets correct for constant errors in the measured
data. Each offset, apart from temperature, is a signed,
sixteen-bit, fixed-point binary number. The bit-weights of
the offsets are the same as that of the final results. The
sixteen-bit offsets provide a numerical range of –32768
to +32767 for voltage, bias current, transmit power, and
receive power.
The numerical range for the six-bit temperature offset is
–32 (–16 °C) to +31 (+15.5 °C) in increments of .5 °C.
The two most significant bits of the temperature offset
coefficient are ignored by the MIC3003.
Computing Internal Calibration Results
Calibration of voltage, bias current, and TX power are
performed using the following calculation:
RESULTn = ADC _ RESULTn × SLOPEn + OFFSETn
(6)
Calibration of RX power is performed using the following
calculation:
RESULT = ADC _ RESULT × SLOPE(m) + OFFSET(m)
(7)
where m represents one of the eight linearization
intervals corresponding to the RX power level.
The results of these calculations are rounded to sixteen
bits. If the seventeenth bit is a one, the result is rounded
up to the next higher value. If the seventeenth bit is zero,
the upper sixteen bits remain unchanged. The bitweights of the offsets are the same as that of the final
results. For SFF-8472 compatible applications, these bitweights are given in Table 10.
Parameter
Magnitude of LSB
Voltage
100µV
Bias Current
2µA
TX Power
0.1µW
RX Power
0.1µW
Table 10. LSB Values of Offset Coefficients
(5)
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Address(s)
Field
Size
HEX
DEC
Name
Description
48-49
72-73
2
RESERVED
Reserved. There is no slope for temperature. Do not write; reads undefined.
4A-4B
74-75
2
TOFFh:TOFFl
Temperature offset; signed six-bit integer offset with an LSB resolution of .5
degrees C per bit. The two most significant bits of TOFFh are ignored.
TOFFl is not used.
4C-4D
76-77
2
VSLPh:VSLPl
Voltage slope; unsigned fixed-point; MSB is at lower physical address.
4E-4F
78-79
2
VOFFh:VOFFl
Voltage offset; signed integer; MSB is at lower physical address.
50-51
80-81
2
ISLPh:ISLPl
Bias current slope; unsigned fixed-point; MSB is at lower physical address.
52-53
82-83
2
IOFFh:IOFFl
Bias current offset; signed integer; MSB is at lower physical address.
54-55
84-85
2
TXSLPh: XSLPl
TX power slope; unsigned fixed-point; MSB is at lower physical address.
56-57
86-87
2
TXOFFh: TXOFFl
TX power slope; unsigned fixed-point; MSB is at lower physical address.
Note that TOFFh is also used in external calibration mode.
Table 11. Internal Calibration Coefficient Memory Map – Part I
Address(s)
Field
Size
HEX
DEC
28-29
40-41
2
RXSLP0h: RXSLP0l
RX power slope 0; unsigned fixed-point; MSB is at lower physical address.
2A-2B
42-43
2
RXOFF0h: RXOFF0l
RX power offset 0; signed integer; MSB is at lower physical address.
2C-2D
44-45
2
RXSLP1h: RXSLP1l
RX power slope 1; unsigned fixed-point; MSB is at lower physical address.
2E-2F
46-47
2
RXOFF1h: RXOFF1l
RX power offset 1; signed integer; MSB is at lower physical address.
30-31
48-49
2
RXSLP2h: RXSLP2l
RX power slope 2; unsigned fixed-point; MSB is at lower physical address.
32-33
50-51
2
RXOFF2h: RXOFF2l
RX power offset 2; signed integer; MSB is at lower physical address.
34-35
52-53
2
RXSLP3h: RXSLP3l
RX power slope 3; unsigned fixed-point; MSB is at lower physical address.
36-37
54-55
2
RXOFF3h: RXOFF3l
RX power offset 3; signed integer; MSB is at lower physical address.
38-39
56-57
2
RXSLP4h: RXSLP4l
RX power slope 4; unsigned fixed-point; MSB is at lower physical address.
Name
Description
3A-3B
58-59
2
RXOFF4h: RXOFF4l
RX power offset 4; signed integer; MSB is at lower physical address.
3C-3D
60-61
2
RXSLP5h: RXSLP5l
RX power slope 5; unsigned fixed-point; MSB is at lower physical address.
3E-3F
62-63
2
RXOFF5h: RXOFF5l
RX power offset 5; signed integer; MSB is at lower physical address.
40-41
64-65
2
RXSLP6h: RXSLP6l
RX power slope 6; unsigned fixed-point; MSB is at lower physical address.
42-43
66-67
2
RXOFF6h: RXOFF6l
RX power offset 6; signed integer; MSB is at lower physical address.
44-45
68-69
2
RXSLP7h: RXSLP7l
RX power slope 7; signed integer; MSB is at lower physical address.
46-47
70-71
2
RXOFF7h: RXOFF7l
RX power offset 7; signed fixed-point; MSB is at lower physical address.
Table 12. Internal Calibration Coefficient Memory Map – Part II
July 2010
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Figure 3. Internal Calibration RX Power Linear Approximation
C/ Reading the ADC Result Registers
The ADC result registers should be read as 16-bit
registers under internal calibration while under external
calibration they should be read as 8-bit or 16-bit
registers at the MSB address. For example, TX power
should be read under internal calibration as 16 bits at
address A2h: 66h–67h and under external calibration as
8 bits at address A2h: 66h. 9-bit temperature results and
12-bit receive power results should always be read as
16-bit quantities.
Reading the result registers using two-byte burst reads on
the SMBus guarantees that the two bytes are coherent
with each other—that is, they form a matched result pair.
If the two bytes were read separately, it is possible that
the internal result could be updated between the reads,
leading to an incorrect ADC result.
RXPOT
A programmable, non-volatile digitally controlled
potentiometer is provided for adjusting the gain of the
receive power measurement signal chain in the analog
domain. Five bits in the RXPOT register are used to set
and adjust the position of potentiometer. RXPOT
functions as a programmable divider or attenuator. It is
adjustable in steps from 1:1 (no divider action) down to
1/32 in steps of 1/32. If RXPOT is set to zero, then the
divider is bypassed completely. There will be no scaling
of the input signal, and the resistor network will be
disconnected from the VRX pin. At all other settings of
RXPOT, there will be a 32kΩ (typical) load seen on
VRX.
July 2010
Figure 4. RXPOT Block Diagram
Laser Diode Bias Control
The MIC3003 can be configured to generate a constant
bias current using electrical feedback, or regulate
average transmitted optical power using a feedback
signal from a monitor photodiode, as shown in Figure 5.
An operational amplifier is used to control laser bias
current via the VBIAS output. The VBIAS pin can drive a
maximum of ±10mA. An external bipolar transistor
provides current gain. The polarity of the op amp’s
output is programmable with BIASREF (bit-5 in
OEMCFG1) in order to accommodate either NPN or
PNP transistors that drive common anode and common
cathode laser, respectively. Additionally, the polarity of
the feedback signal is programmable for use with either
common-emitter or emitter-follower transistor circuits.
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Furthermore, the reference level for the APC circuit is
selectable to accommodate electrical, i.e., current
feedback, or optical feedback via a monitor photodiode.
Finally, any one of seven different internal feedback
resistors can be selected. This internal resistor can be
used alone or in parallel with an external resistor. This
wide range of adjustability (50:1) accommodates a wide
range of photodiode current, i.e., wide range of
transmitter output power. The APC operating point can
be kept near the mid-scale value of the APC DAC,
insuring maximum SNR, maximum effective resolution
for digital diagnostics, and the widest possible DAC
adjustment range for temperature compensation, etc.
See Figure 6.
The APCCAL bit in OEMCAL0 is used to turn the APC
function on and off. It will be turned on in the MIC3003’s
default state as shipped from the factory. When the APC
is on, the value in the selected APCSETx register is
added to the signed compensation value taken from the
APC look-up table and loaded into the VBIAS DAC. When
the APC is off, the VBIAS DAC may be written directly via
the VBIAS register, bypassing the look-up table entirely.
This provides direct control of the laser diode bias during
setup and calibration. In either case, the VBIAS DAC
setting is reported in the APCDAC register.
MIC3003GFL
Figure 6. Programmable Feedback Resistor
Laser Modulation Control
As shown in Figure 5, a temperature-compensated DAC
is provided to set and control the laser modulation
current via an external laser driver circuit. The MODREF
bit in OEMCFG0 selects whether the VMOD DAC output
swings up from ground or down from VDD. If the laser
driver requires a voltage input to set the modulation
current, VMOD output can drive it directly. If a current
input is required, a fixed resistor can be used between
the driver and the VMOD output. Several different
configurations are possible as shown in Figure 8.
When the APC is on, i.e., the APCCAL bit in OEMCAL0
is set to 0, the value corresponding to the current
temperature is taken from the MODLUT look-up table,
added to the selected MODSETx register, and loaded
into the VMOD DAC. When the APC is off, the
compensation value in VMOD is loaded directly into the
VMOD DAC, bypassing the look-up table entirely. This
provides for direct modulation control for setup and
calibration.
Figure 5. APC and Modulation Control
Block Diagram
Figure 7. Transmitter Configurations
Supported by MIC3003
July 2010
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Configuration Bits
Shutdown State
OE
SPOL
SHDN
0
Don’t Care
Hi-Z
1
0
GND
1
1
VDD
Table 13. Shutdown State of SHDN vs.
Configuration Bits
VBIAS Shutdown State
Configuration Bits
OE
INV
BIASREF
VBIAS
0
Don’t Care
Don’t Care
Hi-Z
1
Don’t Care
0
GND
1
Don’t Care
1
VDD
Table 14. Shutdown State of VBIAS vs.
Configuration Bits
Configuration Bits
Figure 8. VMOD Configured as Voltage Output
with Gain
Power On and Laser Start-Up
When power is applied, the MIC3003 initializes its
internal registers and state machine. This process takes
tPOR, about 50ms. Following tPOR, analog-to-digital
conversions begin, serial communication is possible, and
the POR bit and data ready bits may be polled. The first
set of analog data will be available tCONV after tPOR.
MIC3003s are shipped from the factory with the output
enable bit, OE, set to zero, off. The power-up default
state, therefore, is APC off, VBIAS, VMOD, and SHDN
outputs disabled. VBIAS, VMOD, and SHDN will be floating
(high impedance) and the laser diode, if connected, will
be off. Once the device is incorporated into a transceiver
and properly configured, then the shutdown states of
SHDN, VBIAS, and VMOD will be determined by the state of
the APC configuration and OE bits. Tables 13, 14, and
15 illustrate the shutdown states of the various laser
control outputs versus the control bits.
July 2010
VMOD Shutdown State
OE
MODREF
VMOD
0
Don’t Care
Hi-Z
1
0
GND
1
1
VDD
Table 15. Shutdown State of VMOD vs.
Configuration Bits
In order to facilitate hot-plugging, the laser diode is not
turned on until tINIT2 after Power-On. Following tINIT2, and
assuming TXDISABLE is not asserted, the DACs will be
loaded with their initial values. Since tCONV is much less
than tINIT2, the first set of analog data, including
temperature, is available at tINIT2. Temperature
compensation will be applied to the DAC values if
enabled. APC will begin if OE is asserted. (If the output
enable bit, OE, is not set, the VMOD, VBIAS, and SHDN
outputs will float indefinitely.) Figure 9 shows the powerup timing of the MIC3003. If TXDISABLE is asserted at
power-up, the VMOD and VBIAS outputs will stay in their
shutdown states following MIC3003 initialization. A/D
conversions will begin, but the laser will remain off.
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MIC3003GFL
Figure 9. MIC3003 Power-On Timing (OE = 1)
Fault Comparators
In addition to detecting and reporting the events specified
in SFF-8472, the MIC3003 also monitors five fault
conditions: inadequate supply voltage, thermal diode
faults, excessive bias current, excessive transmit power,
and APC op-amp saturation. Comparators monitor these
parameters in order to respond quickly to fault conditions
that could indicate link failure or safety issues, see Figure
10. When a fault is detected, the laser is shut down and
TXFAULT is asserted. Each fault source may be
independently disabled using the FLTMSK register.
FLTMSK is non-volatile, allowing faults to be masked only
during calibration and testing or permanently.
Figure 10. Fault Comparator Logic
July 2010
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Thermal diode faults are detected within the temperature
measurement subsystem when an out-of-range signal is
detected. A window comparator circuit monitors the
voltage on the compensation capacitor to detect APC opamp saturation (Figure 11). Op-amp saturation indicates
that some fault has occurred in the control loop such as
loss of feedback. The saturation detector is blanked for a
time, tFLTTMR, following laser turn-on since the
compensation voltage will essentially be zero at turn-on.
The FLTTMR interval is programmable from 0.5ms to
127.5ms (typical) in increments of 0.5ms (tFLTTMR).
Note that a saturation comparator cannot be relied upon
to meet certain eye-safety standards that require 100ms
response times. This is because the operation of a
saturation detector is limited by the loop bandwidth, i.e.,
the choice of CCOMP. Even if the comparator itself was
very fast, it would be subject to the limited slew-rate of the
APC op-amp. Only the other fault comparator channels
will meet <100ms timing requirements.
The MIC3003 can also except and respond to fault inputs
from external devices. See the “SHDN and TXFIN”
section.
A similar comparator circuit monitors received signal
strength and asserts RXLOS when loss-of-signal is
detected (Figure 12). RXLOS will be asserted if VRX
drops below the level programmed in LOSFLT.
Hysteresis is implemented such that RXLOS will be deasserted when VRX subsequently rises above the level
programmed in LOSFLTn. The loss-of-signal comparator
may be disabled completely by setting the LOSDIS bit in
OEMCFG3. Once the LOS comparator is disabled, an
external device may drive RXLOS. The state of the
RXLOS pin is reported in the CNTRL register regardless
of whether it is driven by the internal comparator or by an
external device. A programmable digital-to-analog
converter provides the comparator reference voltages for
monitoring received signal strength, transmit power, and
bias current. Since laser bias current varies greatly with
temperature, there is a temperature compensation lookup table for the bias current fault DAC value.
When a fault condition is detected, the laser will be
shutdown immediately and TXFAULT will be asserted.
The VMOD, VBIAS, and SHDN (if enabled by setting
OEMCFG5 bit 7 to 1) outputs will be driven to their
shutdown state according to the state of the configuration
bits. The shutdown states of VMOD, VBIAS, and SHDN
versus the configuration bit settings are shown in Table
12, Table 13, and Table 14.
MIC3003GFL
applications in which the MIC3003 is performing all APC
and laser management tasks. The TXFIN function is for
situations in which an external device such as a laser diode
driver IC is performing laser management tasks, including
fault detection.
If the TXFIN bit in OEMCFG3 is zero (the default mode),
SHDN will be activated anytime the laser is off. Thus, it will
be active if 1) TXDISABLE is asserted, 2) STXDIS in the
CNTRL register, is set, or 3) a fault is detected. SHDN is a
push-pull logic output. Its polarity is programmable via the
SPOL bit in OEMCFG1.
If TXFIN bit is set to one, pin 12 serves as an input that
accepts fault signals from external devices such as laser
diode driver ICs. Multiple TXFAULT signals cannot simply
be wire-OR’ed together as they are open-drain and active
high. The input polarity is programmable via the TXFPOL
bit in OEMCFG3. TXFIN is logically OR’ed with the
MIC3003’s internal fault sources to produce TXFAULT and
determine the value of the transmit fault bit in CNTRL. See
Figure 10.
Figure 11. Saturation Detector
SHDN and TXFIN
SHDN and TXFIN are optional functions of pin 12. SHDN
is an output function and is designed to drive a redundant
safety switch in the laser current path. TXFIN is an input
function and serves as an input for fault signals from
external devices that must be reported to the host via
TXFAULT. The SHDN function is designed for
July 2010
Figure 12. RXLOS Comparator Logic
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Temperature Measurement
The temperature-to-digital converter is built around a
switched current source and an eight-bit/nine-bit analogto-digital converter. The temperature is calculated by
measuring the forward voltage of a diode junction at two
different bias current levels. An internal multiplexer directs
the current source’s output to a diode junction. This data
is also used as the input to the temperature
compensation look-up tables. Each time temperature is
sampled and an updated value acquired, new corrective
values for modulation current and the APC setpoint are
read from the corresponding tables, added to the set
values, and transferred to the DACs.
Diode Faults
The MIC3003 is designed to respond in a failsafe manner
to hardware faults in the temperature sensing circuitry. If
there is a fault with the on-chip sensing diode, the
temperature data reported by the A/D converter will be
forced to its full-scale value (+127 °C). The diode fault
flag, DFLT, will be set in OEMCFG0, TXFAULT will be
asserted, and the high temperature alarm and warning
flags will be set. The reported temperature will remain at
+127 °C until the fault condition is cleared. Diode faults
may be reset by toggling TXDISABLE, as with any other
fault. Diode faults will not be detected at power up until
the first A/D conversion cycle is completed.
Temperature Compensation
Since the performance characteristics of laser diodes and
photodiodes change with operating temperature, the
MIC3003 provides a facility for temperature compensation
of the APC. loop set-point, laser modulation current, bias
current fault comparator threshold, and bias current high
alarm flag threshold. Temperature compensation is
performed using a look-up table (LUT) that stores values
corresponding to each measured temperature over a
150°C span. Four identical tables reside at serial address
A4h and A6h as summarized in Table 16. Each table
entry is a signed twos complement integer that is used as
an offset to the parameter being compensated. The
default value of all table entries is zero, giving a flat
response.
The A/D converter reports a new temperature sample
each tCONV. This occurs at roughly 10 Hz when 8-bit
temperature resolution is selected. To prevent
temperature oscillation due to thermal or electrical noise,
sixteen successive temperature samples are averaged
together and used to index the LUT.s. Temperature
compensation results are therefore updated at 16xtCONV
intervals, or about 1.6 seconds. This can be expressed as
shown in Equation 8:
TCOMPm =
July 2010
Tn + Tn+1 + Tn+2 + • • •Tn+15
16
Each time an updated average value is acquired, a new
offset value for the APC setpoint is read from the
corresponding look-up table (see Table 17) and transferred
to the APC circuitry. This is illustrated in Equation 11. In a
same way, new offset values are taken from similar look-up
tables (see Table 18 and Table 19), added to the nominal
values and transferred into the modulation and fault
comparator DACs. The bias current high alarm threshold is
compensated using a fourth look-up table (see Table 20).
This compensation happens internally and does not affect
any host-accessible registers.
APCSETm = APCSETx + APCLUT(TCOMPm )
Table _ min ≤ TCOMPm ≤ Table _ max
APCSETm = APCSETx + APCLUT(max)
TCOMP > Table _ max
APCSETm = APCSETx + APCLUT(min)
TCOMP < Table _ min
(9)
If the measured temperature is greater than the maximum
table value, the highest value in each table is used. If the
measured temperature is less than the minimum, the
minimum value is used. Hysteresis is employed to further
enhance noise immunity and prevent oscillation. Each table
entry spans two degrees C. The table index will not change
unless the new temperature average results in a table index
beyond the midpoint of the next entry in either direction.
There is therefore 2 to 3°C of hysteresis on temperature
compensation changes. The table index will never oscillate
due to quantization noise as the hysteresis is much larger
than ±1⁄2 LSB.
Serial
Address
Byte
Addresses
Function
Base address
+4h
00h–3Fh
APC Look-up Table
40h–7Fh
IMOD Look-up Table
80h–BFh
IFLT Look-up Table
C0h–FFh
Bias High Alarm Look-up Table
58h–63h
APC Look-up Table (cont.)
64h–6Fh
IMOD Look-up Table (cont.)
Base address
+6h
70h–7Bh
IFLT Look-up Table (cont.)
7Ch–87h
Bias High Alarm Look-up Table
(cont.)
Table 16. Temperature Compensation Look-up Tables
(8)
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Serial Address
Base address
+4h
MIC3003GFL
Register
Address
00h
Table
Offset
0
Temperature
Offset (°C)
≤ -45
01h
1
-44
-43
Serial Address
Base address
+4h
Register
Address
80h
Table
Offset
81h
Temperature
Offset (°C)
≤ -45
-44
-43
82h
Base address
+6h
•
•
•
•
•
•
•
•
•
•
•
•
BEh
•
•
•
•
•
•
3Fh
63
BFh
63
64h
64
58
64
•
•
•
•
80
81
82
83
•
•
•
•
•
•
80
81
82
83
•
•
6E
74
62
74
6F
75
63
75
Base address
+6h
102
103
≥ 104
Table 17. APC Temperature Compensation
Look-Up Table
Serial Address
Base address
+4h
Register
Address
40h
Table
Offset
0
Temperature
Offset (°C)
≤ -45
41h
1
-44
-43
102
103
≥ 104
Table 19. IBIAS Comparator Temperature Compensation
Look-Up Table
Serial Address
Base address
+4h
Register
Address
C0h
Table
Offset
C1h
Temperature
Offset (°C)
≤ -45
-44
-43
C2h
Base address
+6h
•
•
•
•
•
•
•
•
•
7Fh
63
70
64
•
•
•
•
80
81
82
83
•
•
7A
74
7B
75
Base address
+6h
102
103
≥ 104
•
•
•
•
•
•
FFh
63
7C
64
•
•
•
•
80
81
82
83
•
•
87
74
102
103
Table 20. BIAS Current High Alarm Temperature
Compensation Table
Table 18. IMOD Temperature Compensation
Look-Up Table
July 2010
•
•
•
FEh
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The internal state machine calculates a new table index
each time a new average temperature value becomes
available. This table index is derived from the average
temperature value. The table index is then converted into
a table address for each of the four look-up tables. These
operations can be expressed as:
INDEX =
TAVG(n )
2
(10)
where TAVG(n) is the current average temperature; and
TABLE_ADDRESS=INDEX+BASE_ADDRESS
where BASE_ADDRESS is the physical base address of
each table, i.e., 00h, 20h, 40h, 80h, or 60h (tables reside in
the Base address + 4h and Base address + 6h pages of
memory).
At any given time, the current table index can be read in
the LUTINDX register.
Alarms and Warning Flags
There are 20 different conditions that will cause the
MIC3003 to set one of the bits in the WARNx or ALARMx
registers. These conditions are listed in Table 21. The
less critical of these events generate warning flags by
setting a bit in WARN0 or WARN1. The more critical
events cause bits to be set in ALARM0 or ALARM1.
An event occurs when any alarm or warning condition
becomes true. Each event causes its corresponding
status bit in ALARM0, ALARM1, WARN0, or WARN1 to
be set. This action cannot be masked by the host. IF
OEMCFG-4 bits [7-4] are set to 0 (default value), the
status bit will remain set until the host reads that
particular status register, a power on-off cycle occurs, or
the host toggles TXDISABLE.
If TXDISABLE is asserted at any time during normal
operation, A/D conversions continue. The A/D results for
all parameters will continue to be reported. All events will
be reported in the normal way. If they have not already
been individually cleared by read operations, when
TXDISABLE is de-asserted, all status registers will be
cleared.
July 2010
Control and Status I/O
The logic for the transceiver control and status I/O is shown
schematically in Figure 13. Note that the internal drivers on
RXLOS/TRSOUT, RRSOUT/GPO, QGPO, and TXFAULT
are all open-drain. These signals may be driven either by
the internal logic or external drivers connected to the
corresponding MIC3003 pins. In any case, the signal level
appearing at the pins of the MIC3003 will be reported in the
control register status bits.
Note that the control bits for TX_DISABLE and RRSOUT,
TRSOUT, and the status bits for TXFAULT and RXLOS do
not meet the timing requirements as specified in the SFP
MSA or the GBIC Specification, revision 5.5 (SFF-8053) for
the hardware signals. The speed of the SMBus serial
interface limits the rate at which these functions can be
manipulated and/or reported. The response time for the
control and status bits is given in the “Electrical
Characteristics” subsection.
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Event
Condition
MIC3003 Response
Temperature high alarm
TEMP > TMAX
Set ALARM0[7]
Temperature low alarm
TEMP < TMIN
Set ALARM0[6]
Voltage high alarm
VIN > VMAX
Set ALARM0[5]
Voltage low alarm
VIN < VMIN
Set ALARM0[4]
TX bias high alarm
IBIAS > IBMAX
Set ALARM0[3]
TX bias low alarm
IBIAS < IBMIN
Set ALARM0[2]
TX power high alarm
TXOP > TXMAX
Set ALARM0[1]
TX power low alarm
TXOP < TXMIN
Set ALARM0[0]
RX power high alarm
RXOP > RXMAX
Set ALARM1[7]
RX power low alarm
RXOP < RXMIN
Set ALARM1[6]
Temperature high warning
TEMP > THIGH
Set WARN0[7]
Temperature low warning
TEMP < TLOW
Set WARN0[6]
Voltage high warning
VIN > VHIGH
Set WARN0[5]
Voltage low warning
VIN < VLOW
Set WARN0[4]
TX bias high warning
IBIAS > IBHIGH
Set WARN0[3]
TX bias low warning
IBIAS < IBLOW
Set WARN0[2]
TX power high warning
TXOP > TXHIGH
Set WARN0[1]
TX power low warning
TXOP < TXLOW
Set WARN0[0]
RX power high warning
RXOP > RXHIGH
Set WARN1[7]
RX power low warning
RXOP < RXLOW
Set WARN1[6]
Table 21. MIC3003 Alarm and Warning Events
Figure 13. Control and Status I/O Logi
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System Timing
The timing specifications for MIC3003 control and status I/O are given in the “Electrical Characteristics” subsection.
Figure 14. Transmitter On-Off Timing
Figure 15. Initialization Timing with TXDISABLE Asserted
Figure 16. Initialization Timing with TXDISABLE Not Asserted
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Figure 17. Loss-of-Signal (LOS) Timing
Figure 18. Transmit Fault Timing
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Figure 19. Successfully Clearing a Fault Condition
Figure 20. Unsuccessful Attempt to Clear a Fault
Warm Resets
The MIC3003 can be reset to its power-on default state
during operation by setting the RST bit in OEMCFG0.
When this bit is set, TXFAULT and RXLOS will be deasserted, all registers will be restored to their normal
power-on default values, and any A/D conversion in
progress will be halted and the results discarded. The
state of the MIC3003 following this operation is
indistinguishable from a power-on reset.
Power-On Hour Meter
The Power-On Hour meter logs operating hours using an
internal real-time clock and stores the result in NVRAM.
The hour count is incremented at ten-hour intervals in the
middle of each interval. The first increment therefore
takes place five hours after power-on. Time is
accumulated whenever the MIC3003 is powered. The
hour meter’s time base is accurate to +/-10% over all
MIC3003 operating conditions, and is accurate to +/-5%
in the range 0 to 70 degrees C. The counter is capable of
storing counts of more than thirty years, but is ultimately
limited by the write-cycle endurance of the non-volatile
memory. This implies a range of at least twenty years.
July 2010
Actual results will depend upon the operating conditions
and write-cycle endurance of the part in question.
Two registers, POHh and POHl, contain a 15-bit power-on
hour measurement and an error flag, POHFLT. Great care
has been taken to make the MIC3003’s hour meter immune
to data corruption and to insure that valid data is maintained
across power cycles. The hour meter employs multiple data
copies and error correction codes to maintain data validity.
This data is stored in the POHDATA registers. If POHFLT is
set, however, the power-on hour meter data has been
corrupted and should be ignored.
It is recommended that a two-byte sequential read
operation be performed on POHh and POHl to insure
coherency between the two registers. These registers are
accessible by the OEM using a valid OEM password. The
only operation that should be performed on these registers
is to clear the hour meters initial value, if necessary, at the
time of product shipment. The hour meter result may be
cleared by setting all eight POHDATA bytes to 00h.
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Test and Calibration Features
Numerous features are included in the MIC3003 to
facilitate development, testing, and diagnostics. These
features are available via registers in the OEM area. As
shown in Table 22, these features include:
Function
Description
Control
Register(s)
Analog loop-back
Provides analog visibility of op-amp and DAC outputs via the ADC
OEMCFG0
Fault comparator disable control
Disables the fault comparator
OEMCAL0
Fault comparator spin-on-channel
mode
Selects a single fault comparator channel
OEMCAL0
Fault comparator output read-back
Allows host to read individual fault comparator outputs
OEMRD
TRSOUT, /INT read-back
Allows host to read the state of these pins
OEMRD
Inhibit EEPROM write cycles
Speeds repetitive writes to registers backed up by NVRAM
OEMCAL0
APC calibration mode
Allows direct writes to MODDAC and APCDAC (temperature
compensation not used)
OEMCAL0
Continuity checking
Forcing of RXLOS, TXFAULT, /INT
OEMCAL0
Halt A/D
Stops A/D conversions; ADC in one-shot mode
OEMCAL1
ADC idle flag
Indicates ADC status
OEMCAL1
A/D one-shot mode
Performs a single A/D conversion on the selected input channel
OEMCAL1
A/D spin-on-channel mode
Selects a single input channel
OEMCAL1
Channel selection
Selects ADC or fault comparator channel for spin-on-channel
modes
OEMCAL1
LUT index read-back
Permits visibility of the LUT index calculated by the state-machine
LUTINDX
Manufacturer and device ID registers
Facilitates presence detection and version control
MFG_ID,
DEV_ID
Table 22. Test and Diagnostic Features
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Serial Port Operation
The MIC3003 uses standard write byte, read byte, and
read word operations for communication with its host. It
also supports block write and block read transactions.
The write byte operation involves sending the devices
address (with the R/W bit low to signal a write operation),
followed by the address of the register to be operated
upon and the data byte. The read byte operation is a
composite write and read operation: the host first sends
the devices address followed by the register address, as
in a write operation. A new start bit must then be sent to
the MIC3003, followed by a repeat of the device address
with the R/W bit (LSB) set to the high (read) state. The
data to be read from the part may then be clocked out. A
read word is similar, but two successive data bytes are
clocked out rather than one. These protocols are shown
in Figures 21 to 24.
The MIC3003 will respond to up to four sequential device
addresses depending upon whether it is in OEM or User
mode. A match between one of the MIC3003’s addresses
and the address specified in the serial bit stream must be
made to initiate communication. The MIC3003 responds
to device addresses A0h and A2h in User Mode; it also
responds to A4h and A6h in OEM Mode (assuming the
base address is A0h).
Block Writes
To increase the speed of block writes, the MIC3003 allows
up to eight consecutive bytes to be written before the
internal memory update begins.
The block write sequence begins just like a write byte
operation with the host sending the device address, R/W bit
low, register address, etc. After the first data byte is sent
the host will receive an acknowledge. Up to seven more
bytes can be sent in sequence. The MIC3003 will
acknowledge each one and increment its internal address
register in anticipation of the next byte. After the last byte is
sent, the host issues a STOP. The MIC3003’s internal write
process then begins.
Block writes of up to eight bytes can begin and end at any
byte address without restriction. Block writes that increment
over register address FFh will simply “wrap around” and
continue at address 00h within the same device address
space.
To accelerate calibration and testing, NVRAM write cycles
can be disabled completely by setting the WRINH bit in
OEMCAL0. Writes to registers that do not have NVRAM
backup, will not incur write-cycle delays when writes are
inhibited. Write operations on registers that exist only in
NVRAM will still incur write cycle delays.
Figure 21. Write Byte Protocol
Figure 22. Read Byte Protocol
Figure 23. Read_Word Protocol
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Figure 24. Eight-Byte Block Write Protocol
Acknowledge Polling
The MIC3003’s non-volatile memory cannot be accessed
during the internal memory update. To allow for maximum
speed bulk writes, the MIC3003 supports acknowledge
polling. The MIC3003 will not acknowledge serial bus
transactions while internal writes are in progress. The
host may therefore monitor for the end of the write
process
by
periodically
checking
for
an
acknowledgement. The longest duration for the internal
memory update to complete for a block write is
approximately 26 ms.
Write Protection and Data Security
OEM Password
A password is required to access the OEM areas of the
MIC3003, specifically the non-volatile memory, look-up
tables, and registers at serial addresses A4h and A6h. A
four-byte field, OEMPWSET, at serial address A6h is
used for setting the OEM password. The OEM password
is set by writing OEMPWSET with the new value. The
password comparison is performed following the write to
the MSB of the OEMPW, address 7Bh (or 7Eh if
OEMCFG5 bit 2 is set to 1) at serial address A2h.
Therefore, this byte must be written last. A four-byte
burst-write sequence to address 78h (or 7Bh if OEMCFG5
bit 2 is set to 1) may be used as this will result in the
MSbyte being written last. New passwords written to the
OEMPWSET registers will not take effect until after a
power-on reset occurs or a warm reset is performed using
the RST bit in OEMCFG0. This allows the new password
to be verified before it takes effect.
July 2010
The corresponding four-byte field for password entry,
OEMPW, is located at serial address A2h. This field is
therefore always visible to the host system. OEMPW is
compared to the four-byte OEMPWSET field at serial
address A6h. If the two fields match, access is allowed to
the OEM areas of the MIC3003 non-volatile memory at
serial addresses A4h and A6h. If OEMPWSET is all zeroes,
no password security will exist. The value in OEMPW will
be ignored. This helps prevent a deliberately unsecured
MIC3003 from being inadvertently locked. Once a valid
password is entered, the MIC3003 OEM areas will be
accessible. The OEM areas may be re-secured by writing
an incorrect password value at OEMPW, e.g., all zeroes. In
all cases, OEMPW must be written LSB first through MSB
last. The OEM areas will be inaccessible following the final
write operation to OEMPW’s LSB. The OEMPW field is
reset to all zeros at power on. Any values written to these
locations will be readable by the host regardless of the
locked/unlocked status of the device. If OEMPWSET is set
to zero (00000000h), the MIC3003 will remain unlocked
regardless of the contents of the OEMPW field. This is the
factory default security setting.
Note that a valid OEM password allows access to the OEM
and user areas of the chip, i.e., the entire memory map.
OEM Mode and User Mode
When the OEM password is unlocked (either by matching
the set password or if the password is all zeros), the
MIC3003 is in OEM Mode. If the part is locked, the part is in
User Mode.
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Detailed Register Descriptions
Note: Serial bus addresses shown assume that the base device address is AOh.
Alarm Threshold Registers
Temperature High Alarm Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 °C)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (TMAXh): 00 = 00h
Byte addresses
LS byte (TMAXl): 01 = 01h
Each LS bit of TMAXh represents one degree Celsius. TMAXl is not used, since all limit comparisons for temperature use
eight-bit values.
The eight bits of the high alarm threshold value (TMAXh) are compared to the temperature result (TEMPh). ALARM0 bit 7 is
set if Result > Threshold.
Temperature Low Alarm Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 °C)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (TMINh): 02 = 02h
Byte addresses
LS byte (TMINl): 03 = 03h
Each LS bit of TMINh represents one degree Celsius. TMINl is not used, since all limit comparisons for temperature use eightbit values..
The eight MS bits of the low alarm threshold value (TMINh) are compared to the temperature result (TEMPh). ALARM0 bit 6 is
set if Result < Threshold.
Voltage High Alarm Threshold
D[7]
read/write
D[6]
read/write
D[5]
read/write
D[4]
read/write
D[3]
read/write
Default value for both bytes
0000 0000b = 00h (0 V)
Serial address
A2h
MS byte (VMAXh): 08 = 08h
Byte addresses
D[2]
read/write
D[1]
read/write
D[0]
read/write
LS byte (VMAXl): 09 = 09h
Each LS bit of VMAXh represents 25.6 mV and each LS bit of VMAXl represents 0.1 mV. The sixteen-bit threshold value
(VMAXh:VMAXl) is compared to the sixteen bits value of the voltage result (VINh:VINl). ALARM0 bit 5 is set if
Result > Threshold.
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Voltage Low Alarm Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 V)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (VMINh): 10 = 0Ah
Byte addresses
LS byte (VMINl): 11 = 0Bh
Each LS bit of VMINh represents 25.6 mV and each LS bit of VMINl represents 0.1 mV. The sixteen-bit threshold value
(VMINh:VMINl) is compared to the sixteen-bit value of the voltage result (VINh:VINl). ALARM0 bit 4 is set if Result < Threshold.
Bias Current High Alarm Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mA)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (IMAXh): 16 = 10h
Byte addresses
LS byte (IMAXl): 17 = 11h
Each LS bit of IMAXh represents 512 μA and each LS bit of IMAXl represents 2 μA. The sixteen-bit threshold value
(IMAXh:IMAXl) is compared to the sixteen-bit value of the bias current result (ILDh:ILDl). ALARM0 bit 3 is set if Result >
Threshold.
Bias Current Low Alarm Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mA)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (IMINh): 18 = 12h
Byte addresses
LS byte (IMINl): 19 = 13h
Each LS bit of IMINh represents 512 μA and each LS bit of IMINl represents 2 μA. The sixteen-bit threshold value
(IMINh:IMINl) is compared to the sixteen-bit value of the bias current result (ILDh:ILDl). ALARM0 bit 2 is set if
Result < Threshold.
TX Optical Power High Alarm Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
Serial address
Byte addresses
D[5]
read/write
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mW)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (TXMAXh): 24 = 18h
LS byte (TXMAXl): 25 = 19h
Each LS bit of TXMAXh represents 25.6 μW, and each LS bit of TXMAXl represents 0.1 μW. The sixteen-bit threshold value
(TXMAXh:TXMAXl) is compared to the sixteen-bit value of the TX power result (TXOPh:TXOPl). ALARM0 bit 1 is set if Result >
Threshold.
July 2010
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TX Optical Power Low Alarm Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mW)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (TXMINh): 26 = 1Ah
Byte addresses
LS byte (TXMINl): 27 = 1Bh
Each LS bit of TXMINh represents 25.6 μW, and each LS bit of TXMINl represents 0.1 μW. The sixteen-bit threshold value
(TXMINh:TXMINl) is compared to the sixteen-bit value of the TX power reading (TXOPh:TXOPl). ALARM0 bit 0 is set if
Result < Threshold.
RX Optical Power High Alarm Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mW)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (RXMAXh): 32 = 20h
Bytes addresses
LS byte (RXMAXl): 33 = 21h
Each LS bit of RXMAXh represents 25.6 μW, and each LS bit of RXMAXl represents 0.1 μW. The sixteen-bit threshold value
(RXMAXh:RXMAXl) is compared to the sixteen-bit value of the RX power result (RXOPh:RXOPl). ALARM1 bit 7 is set if
Result > Threshold.
RX Optical Power Low Alarm Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
Serial Address
Byte Address
D[5]
read/write
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0mW)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (RXMINh): 34 = 22h
LS byte (RXMINl): 35 = 23h
Each LSB of RXMINh represents 25.6 μW, and each LS bit of RXMINl represents 0.1 μW. The sixteen-bit threshold value
(RXMINh:RXMINl) is compared to the sixteen-bit value of the RX power result (RXOPh:RXOPl). ALARM1 bit 6 is set if
Result < Threshold.
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Warning Threshold Registers
Temperature High Warning Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 °C)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (THIGHh): 04 = 04h
Bytes addresses
LS byte (THIGHl): 05 = 05h
Each LS bit of THIGHh represents one degree Celsius. THIGHl is not used, since all limit comparisons for temperature use
eight-bit values.
The eight bits of the high warning threshold value (THIGHh) are compared to the temperature result (TEMPh). WARN0 bit 7 is
set if Result > Threshold.
Temperature Low Warning Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 °C)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (TLOWh): 06 = 06h
Bytes addresses
LS byte (TLOWl): 07 = 07h
Each LS bit of TLOWh represents one degree Celsius. TLOWl is not used, since all limit comparisons for temperature use
eight-bit values.
The eight bits of the high warning threshold value (TLOWh) are compared to the temperature result (TEMPh). WARN0 bit 6 is
set if Result < Threshold.
Voltage High Warning Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
Serial address
Bytes addresses
D[5]
read/write
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 V)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (VHIGHh): 12 = 0Ch
LS byte (VHIGHl): 13 = 0Dh
Each LS bit of VHIGHh represents 25.6 mV and each LS bit of VHIGHl represents 0.1 mV. The sixteen-bit threshold value
(VHIGHh:VHIGHl) is compared to the sixteen bits value of the voltage result (VINh:VINl). WARN0 bit 5 is set if
Result > Threshold.
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MIC3003GFL
Voltage Low Warning Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 V)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (VLOWh): 14 = 0Eh
Byte addresses
LS byte (VLOWl): 15 = 0Fh
Each LS bit of VLOWh represents 25.6 mV and each LS bit of VLOWl represents 0.1 mV. The sixteen-bit threshold value
(VLOWh:VLOWl) is compared to the sixteen-bit value of the voltage result (VINh:VINl). WARN0 bit 4 is set if
Result < Threshold.
Bias Current High Warning Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mA)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (IHIGHh): 20 = 14h
Bytes addresses
LS byte (IHIGHl): 21 = 15h
Each LS bit of IHIGHh represents 512 μA and each LS bit of IHIGHl represents 2 μA. The sixteen-bit threshold value
(IHIGHh:IHIGHl) is compared to the sixteen-bit value of the bias current result (ILDh:ILDl). WARN0 bit 3 is set if Result >
Threshold.
Bias Current Low Warning Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mA)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (ILOWh): 22 = 16h
Bytes addresses
LS byte (ILOWl): 23 = 17h
Each LS bit of ILOWh represents 512 μA and each LS bit of ILOWl represents 2 μA. The sixteen-bit threshold value
(ILOWh:ILOWl) is compared to the sixteen-bit value of the bias current result (ILDh:ILDl). WARN0 bit 2 is set if
Result < Threshold.
TX Optical Power High Warning
D[7]
D[6]
read/write
read/write
Default value for both bytes
Serial address
Bytes addresses
D[5]
read/write
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mW)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (TXHIGHh): 28 = 1Ch
LS byte (TXHIGHl): 29 = 1Dh
Each LS bit of TXHIGHh represents 25.6 μW, and each LS bit of TXHIGHl represents 0.1 μW. The sixteen-bit threshold value
(TXHIGHh:TXHIGHl) is compared to the sixteen-bit value of the TX power result (TXOPh:TXOPl).WARN0 bit 1 is set if Result >
Threshold.
July 2010
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MIC3003GFL
TX Optical Power Low Warning
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mW)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (TXLOWh): 30 = 1Eh
Byte addresses
LS byte (TXLOWl): 31 = 1Fh
Each LS bit of TXLOWh represents 25.6 μW, and each LS bit of TXLOWl represents 0.1 μW. The sixteen-bit threshold value
(TXLOWh:TXLOWl) is compared to the sixteen-bit value of the TX power reading (TXOPh:TXOPl). ALARM0 bit 0 is set if
Result < Threshold.
RX Optical Power High Warning Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mW)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (RXHIGHh): 36 = 24h
Byte addresses
LS byte (RXHIGHl): 37 = 25h
Each LS bit of RXHIGHh represents 25.6 μW, and each LS bit of RXHIGHl represents 0.1 μW. The sixteen-bit threshold value
(RXHIGHh:RXHIGHl) is compared to the sixteen-bit value of the RX power result (RXOPh:RXOPl). WARN1 bit 7 is set if
Result > Threshold.
RX Optical Power Low Warning Threshold
D[7]
D[6]
read/write
read/write
Default value for both bytes
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h (0 mW)
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
MS byte (RXLOWh): 38 = 26h
Byte addresses
LS byte (RXLOWl): 39 = 27h
Each LSB of RXLOWh represents 25.6 μW, and each LS bit of RXLOWl represents 0.1 μW. The sixteen-bit threshold value
(RXLOWh:RXLOWl) is compared to the sixteen-bit value of the RX power result (RXOPh:RXOPl). WARN1 bit 6 is set if
Result < Threshold.
Checksum (CHKSUM)
Checksum of bytes 0 - 94 at serial address A2h
D[7]
read/write
Default value
Serial address
Byte address
D[6]
read/write
D[5]
read/write
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A2h
95 = 5Fh
This register is provided for compliance with SFF-8472. It is implemented as general-purpose non-volatile memory. Read/write
access is possible whenever a valid OEM password has been entered. CHKSUM is read-only in User Mode.
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MIC3003GFL
ADC Result Registers
Temperature Result
D[7]
read-only
Serial address
D[6]
read-only
D[5]
read-only
Byte addresses
D[4]
read-only
A2h
D[3]
read-only
D[2]
read-only
D[1]
read-only
D[0]
read-only
MS byte (TEMPh): 96 = 60h
LS byte (TEMPl): 97 = 61h
Each LS bit of TEMPh represents one degree Celsius. The TEMPh register is to be used in conjunction with the most
significant bit of TEMPl to yield an eight-bit or nine-bit signed (two’s complement) temperature value.
If OEMCFG6 bit 1 is set to zero, temperature is read to 1 °C resolution in TEMPh only, and TEMPl is zero.
If OEMCFG6 bit 1 is set to one, then temperature is read to 0.5 °C resolution as a nine-bit value consisting of TEMPh and the
MS bit of TEMPl. The lower seven bits of TEMPl are zero.
TEMPh will contain measured temperature data after the completion of one conversion.
Voltage
D[7]
read-only
Default Value
D[6]
read-only
D[5]
read-only
D[4]
read-only
Serial address
D[3]
read-only
0000 0000b = 00h (0V)(2)
A2h
Byte addresses
MS byte (VINh): 98 = 62h
D[2]
read-only
D[1]
read-only
D[0]
read-only
LS byte (VINl): 99 = 63h
Each LSB of VINh represents 25.6 mV, and each LS bit of VINl represents 0.1 mV. VINh is used in conjunction with VINl to
yield an unsigned sixteen-bit value.
In external calibration mode, the host should process the results using the appropriate slope and offset coefficients. VINh
contains the eight-bit ADC result and VINl is zero.
In internal calibration mode, the MIC3003’s ALU applies the coefficients stored in (VSLPh:VSLPl) and (VOFFh:VOFFl).
The VIN registers will contain valid data after one ADC conversion cycle.
Notes:
1. TEMPh will contain measured temperature data after the completion of one conversion.
2. VINh will contain measured data after one A/D conversion cycle.
Laser Diode Bias Current
D[7]
read-only
Default Value
Serial address
Byte addresses
D[6]
read-only
D[5]
read-only
D[4]
read-only
D[3]
read-only
D[2]
read-only
D[1]
read-only
D[0]
read-only
0000 0000b = 00h (0mA)(3)
A2h
MS byte (ILDh):100 = 64h
LS byte (ILDl):101 = 65h
Each LSB of ILDh represents 512 μA, and each LS bit of ILDl represents 2 μA. ILDh is used in conjunction with ILDl to yield an
unsigned sixteen-bit value.
In external calibration mode, the host should process the results using the appropriate slope and offset coefficients. ILDh
contains the eight-bit ADC result and ILDl is zero.
In internal calibration mode, the MIC3003’s ALU applies the coefficients stored in (ISLPh:ISLPl) and (IOFFh:IOFFl).
The ILD registers will contain valid data after one ADC conversion cycle.
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MIC3003GFL
Transmitted Optical Power
D[7]
read-only
Default Value
D[6]
read-only
D[5]
read-only
D[4]
read-only
D[3]
read-only
D[2]
read-only
D[1]
read-only
D[0]
read-only
0000 0000b = 00h (0mW)(4)
Serial address
A2h
MS byte (TXOPh): 102 = 66h
Byte address
LS byte (TXOPl): 103 = 67h
Each LSB of TXOPh represents 25.6 μW, and each LS bit of TXOPl represents 0.1 μW. TXOPh is used in conjunction with
TXOPl to yield an unsigned sixteen-bit value.
In external calibration mode, the host should process the results using the appropriate slope and offset coefficients. TXOPh
contains the eight-bit ADC result and TXOPl is zero.
In internal calibration mode, the MIC3003’s ALU applies the coefficients stored in (TXSLPh:TXSLPl) and (TXOFFh:TXOFFl).
The TXOP registers will contain valid data after one ADC conversion cycle.
Notes:
3. ILDh will contain measured data after one A/D conversion cycle.
4. TXOPh will contain measured data after one A/D conversion cycle.
Received Optical Power
D[7]
read-only
Default Value
D[6]
read-only
D[5]
read-only
D[4]
read-only
Serial address
D[3]
read-only
0000 0000b = 00h (0mW)(6)
A2h
Byte address
MS byte (RXOPh): 104 = 68h
D[2]
read-only
D[1]
read-only
D[0]
read-only
LS byte (RXOPl): 105 = 69h
Each LSB of RXOPh represents 25.6 μW, and each LS bit of RXOPl represents 0.1 μW.RXOPh is used in conjunction with
RXOPl to yield an unsigned sixteen-bit value.
In external calibration mode, the host should process the results using the appropriate slope and offset coefficients. RXOPh
contains the twelve-bit ADC result and the lower four bits of RXOPl are zero.
In internal calibration mode, the MIC3003’s ALU applies the coefficients stored in (RXSLP[0-7]h:RXSLP[0-7]l) and
(RXOFF[0-7]h:RXOFFl[0-7]).
The RXOP registers will contain valid data after one ADC conversion cycle.
Control and Status (CNTRL)
D[7]
TXDIS
read-only
Default value
D[6]
STXDIS
read/write
D[5]
RS1S
read-only
D[4]
RS0S
read-only
D[3]
SRS0
read/write
Serial address
D[1]
LOS
read-only
D[0]
POR
read-only
A2h
110 = 6Eh
Byte address
July 2010
D[2]
TXFLT
read-only
0000 0000b = 00h
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Bit(s)
D[7]
TXDIS
D[6]
STXDIS
Function
Operation
Reflects the state of the TXDISABLE pin
1 = disabled,
Soft transmit disable STXDIS is Ored with TXDIS
to control the laser which will be turned off if one
of these two signals is set to 1
1 = disabled
Reflects the state of RS1 (pin 10)
1 = RS1 is high (>4.25 Gbps);
0 = enabled
D[5]
RS1S
0 = enabled
0 = RS1 is low (≤4.25 Gbps)
D[4]
RS0S
Reflects the state of RS0 (pin 4)
1 = RS0 is high (>4.25 Gbps)
0 = RS0 is low (≤4.25 Gbps)
D[3]
SRS0
Soft rate select (sets the state of the RS0 pin)
1 = Set RS0 high
0 = Set RS0 low
D[2]
TXFLT
D[1]
LOS
Reflects the state of the TXFAULT pin
1 = TXFAULT is high (fault)
0 = TXFAULT low (no fault)
D[0]
POR
Loss Of Signal. Reflects the state of the RXLOS
pin
1 = RXLOS is high (loss of signal)
MIC3003 power-on status
0 = POR complete, all analog data results
have been converted at least once
1 = POR and first ADC sample cycle in
progress
0 = RXLOS is low (no loss of signal)
Application Select Control Mode (ASCM)
D[7-6]
Control bits
read/write
D[5-0]
Table select
read/write
0000 0000b = 00h
Default value
Serial address
A2h
111 = 6Fh
Byte address
July 2010
Bit(s)
Function
D[7-6]
Application Select Control Bits
D[5-0]
Table Select
Operation
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Bit 7
Bit 6
0
0
0
1
July 2010
1
X
Rate Select/Extended Rate Select Emulation Mode:
•
RS0 (pin 4) controls RRSOUT( pin 23)
•
RS1 (pin 10) does not control TRSOUT (pin24)
•
Byte 110 bit 3 controls RRSOUT (pin 23)
•
Byte 118 bit 3 controls TRSOUT (pin 24)
Hardware Application Select Mode:
•
RS0 (pin 4) controls RRSOUT( pin 23)
•
RS1 (pin 10) controls TRSOUT (pin 24)
•
Byte 110 bit 3 does not control RRSOUT (pin 23)
•
Byte 118 bit 3 does not control TRSOUT (pin 24)
Software Mode:
•
RS0 (pin4) does not control RRSOUT( pin 23)
•
RS1 (pin10) does not control TRSOUT (pin 24)
•
Byte 110 bit 3 does not control RRSOUT (pin 23)
•
Byte 118 bit 3 does not control TRSOUT (pin 24)
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MIC3003GFL
Alarm Flags
Alarm Status Register 0 (ALARM0)
D[7]
A7
read-only
Default value
D[6]
A6
read-only
D[5]
A5
read-only
Serial address
D[4]
D[3]
D[2]
A4
A3
A2
read-only
read-only
read-only
0000 0000b = 00h (no events pending)
D[1]
A1
read-only
D[0]
A0
read-only
A2h
112 = 70h
Byte address
The power-up default value is 00h. Following the first complete A/D conversion cycle, however, any of the bits may be set
depending upon the results.
Bit(s)
Function
Operation
D[7]
A7
High temperature alarm, TEMP > TMAX
1 = condition exists, 0 = normal/OK
D[6]
A6
Low temperature alarm, TEMP < TMIN
1 = condition exists, 0 = normal/OK
D[5]
A5
High voltage alarm, VIN > VMAX
1 = condition exists, 0 = normal/OK
D[4]
A4
Low voltage alarm, VIN < VMIN
1 = condition exists, 0 = normal/OK
D[3]
A3
High laser diode bias alarm, IBIAS > IMAX
1 = condition exists, 0 = normal/OK
D[2]
A2
Low laser diode bias alarm, IBIAS < IMIN
1 = condition exists, 0 = normal/OK
D[1]
A1
High transmit optical power alarm,
TXOP > TXMAX
1 = condition exists, 0 = normal/OK
D[0]
A0
Low transmit optical power alarm,
TXOP < TXMIN
1 = condition exists, 0 = normal/OK
D[7]
A15
read-only
Default value
D[6]
A14
read-only
Alarm Status Register 1 (ALARM1)
D[5]
reserved
D[4]
reserved
D[3]
reserved
D[2]
reserved
D[1]
reserved
D[0]
reserved
0000 0000b = 00h (no events pending)
Serial address
A2h
113 = 71h
Byte address
The power-up default value is 00h. Following the first complete A/D conversion cycle, however, either of the bits may be set
depending upon the results.
Bit(s)
Function
Operation
D[7]
A15
High received power (overload) alarm, RXOP > RXMAX
1 = condition exists, 0 = normal/OK
D[6]
A14
Low received power (LOS) alarm, RXOP < RXMIN
1 = condition exists, 0 = normal/OK
Reserved
Reserved, returns zero on reads
D[5:0]
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MIC3003GFL
Warning Flags
Warning Status Register 0 (WARN0)
D[7]
W7
read-only
D[6]
W6
read-only
D[5]
W5
read-only
Default value
D[4]
D[3]
D[2]
W4
W3
W2
read-only
read-only
read-only
0000 0000b = 00h (no events pending)
D[1]
W1
read-only
D[0]
W0
read-only
A2h
116 = 74h
Serial address
Byte address
The power-up default value is 00h. Following the first complete A/D conversion cycle, however, any of the bits may be set
depending upon the results.
Function
Operation
D[7]
Bit(s)
W7
High temperature warning, TEMP > THIGH
1 = condition exists, 0 = normal/OK
D[6]
W6
Low temperature warning, TEMP < TLOW
1 = condition exists, 0 = normal/OK
D[5]
W5
High voltage warning, VIN > VHIGH
1 = condition exists, 0 = normal/OK
D[4]
W4
Low voltage warning, VIN < VLOW
1 = condition exists, 0 = normal/OK
D[3]
W3
High laser diode bias warning, IBIAS > IHIGH
1 = condition exists, 0 = normal/OK
D[2]
W2
Low laser diode bias warning, IBIAS < ILOW
1 = condition exists, 0 = normal/OK
D[1]
W1
High transmit optical power warning,
TXOP > TXHIGH
1 = condition exists, 0 = normal/OK
D[0]
W0
Low transmit optical power warning,
TXOP < TXLOW
1 = condition exists, 0 = normal/OK
Warning Status Register 1 (WARN1)
D[7]
W15
read-only
D[6]
W14
read-only
D[5]
read-only
D[4]
D[3]
D[2]
D[1]
D[0]
read-only
read-only
read-only
read-only
read-only
Default Value
0000 0000b = 00h (no events pending)
Serial Address
A2h
Byte Address
117 = 75h
The power-up default value is 00h. Following the first complete A/D conversion cycle, however, either of the bits may be set
depending upon the results.
Function
Operation
D[7]
Bit(s)
W15
Received power high warning, RXOP > RXHIGH
1 = condition exists, 0 = normal/OK
D[6]
W14
Received power low warning, RXOP < RXMIN
1 = condition exists, 0 = normal/OK
Reserved
Reserved, returns zero on reads
D[5:0]
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MIC3003GFL
Extended Control and Status (ECNTRL)
D[7]
reserved
D[6]
reserved
D[5]
reserved
D[4]
reserved
D[3]
SRS1
read/write
D[2]
reserved
Default Value
0000 0000b = 00h
Serial Address
A2h
118 = 76h
Byte Address
Bit(s)
D[7-4]
D[3]
SRS1
D[2]
D[1]
PLOS
read/write
D[0]
PLS
read/write
Function
Operation
Reserved
Reserved—always read as zeros
Soft rate select (RS1)
Assert the TRSOUT pin in Rate
Select/Extended Rate Select Emulation
Mode
Reserved
Reserved—always reads as zero
D[1]
PLOS
Power Level Operation State
D[0]
PLS
Power Level Select
These two bits are read/write but change
no functionality of the MIC3003
D[7]
read/write
D[6]
read/write
OEM Password Entry (OEMPW)
D[5]
read/write
D[4]
read/write
D[3]
read/write
D[2]
read/write
Default value for all four bytes
0000 0000b = 00h (reset to zero at power-on)
Serial address
A2h
Byte addresses
If OEMCFG5-2 = 0: 120 – 123 = 78h – 7Bh
If OEMCFG5-2 = 1: 123 – 126 = 7Bh – 7Eh
D[1]
read/write
D[0]
read/write
This four-byte field is for entry of the password required to access the OEM area of the MIC3003’s memory and registers. A
valid OEM password will also permit access to the user areas of memory. This field is compared to the four-byte OEMPWSET
field at serial address A6h, bytes 12 - 15 (0Ch – 0Fh). If the two fields match, access is allowed to the OEM areas of the
MIC3003 non-volatile memory at serial addresses A4h and A6h. The OEM password is set by writing the new value into
OEMPWSET. The password comparison is performed following the write to the highest address byte of OEMPW, address 7Bh
if OEMCFG5 bit 2 is low, or 7Eh if OEMCFG5 bit 2 is high. This byte must be written last.
A four-byte burst-write sequence to OEMPW may be used as this will result in the highest address byte being written last.
OEMPW is reset to zero at power on. Any values written to OEMPW will be readable by the host regardless of the
locked/unlocked status of the device. If OEMPWSET is set to zero (00000000h), the MIC3003 will remain unlocked regardless
of the contents of the OEMPW field. This is the factory default security setting.
Byte
Weight
3
OEM Password Entry, Most Significant Byte (Address = 7Bh resp. 7Eh)
2
OEM Password Entry, 2nd Most Significant Byte (Address = 7Ah resp. 7Dh)
1
OEM Password Entry, 2nd Least Significant Byte (Address = 79h resp. 7Ch)
0
OEM Password Entry, Least Significant Byte (Address = 78h resp. 7Bh)
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MIC3003GFL
Power-On Hours (POHh and POHl)
D[7]
D[6]
D[5]
D[4]
read/write
read/write
read/write
read/write
Default value of both bytes when the
0000 0000b = 00h
MIC3003 is shipped from the factory
D[3]
read/write
Serial address
A6h
Bytes addresses
MS byte (POHh): 251 = FBh
D[2]
read/write
D[1]
read/write
D[0]
read/write
LS byte (POHl): 252 = FCh
The lower seven bits of POHh contain the most significant bits of the 15-bit power-on hours measurement. The value in POHh
should be combined with the eight-bit power-on hours low byte, POHl, to yield the complete result.
The most significant bit of POHh, POHFLT, is an error flag. If POHFLT is set, the power-on hour meter data has been
corrupted and should be ignored.
It is recommended that a two-byte sequential (block) SMBus read operation be performed on POHh and POHl to insure
coherency between the two registers.
This register is non-volatile and will be maintained through power and reset cycles, including unanticipated power failures.
POHh Bit(s)
Function
Operation
D[7]
Power-on hours fault flag, POHFLT
1 = fault: the power-on hours value is corrupted and cannot
be relied upon
D[6:0]
Power-on hours, most significant seven bits
0 = no fault: the power-on hours value is correct
Data Ready Flags (DATARDY)
D[7]
TRDY
read/write
Default value
D[6]
VRDY
read/write
D[5]
IRDY
read/write
D[4]
D[3]
TXRDY
RXDY
read/write
read/write
0000 0000b = 00h
Serial address
A6h
Byte address
253 = FDh
D[2]
reserved
D[1]
reserved
D[0]
reserved
When the A/D conversion for a given parameter is completed and the results available to the host, the appropriate data ready
flag will be set. The flag will be cleared when the host reads the corresponding result register.
Bit(s)
Function
Operation
D[7]
TRDY
Temperature data ready flag
0 = Result register contains old data; 1 = new data ready
D[6]
VRDY
Voltage data ready flag
0 = Result register contains old data; 1 = new data ready
D[5]
IRDY
Bias current data ready flag
0 = Result register contains old data; 1 = new data ready
D[4]
TXRDY
Transmit power data ready flag
0 = Result register contains old data; 1 = new data ready
D[3]
RXRDY
Receive power data ready flag
0 = Result register contains old data; 1 = new data ready
Reserved
Reserved
D[2:0]
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MIC3003GFL
User Control Register (USRCTL)
D[7]
Reserved
read/write
Default value
D[6]
PORM
read/write
D[5]
PORS
read/write
Serial address
D[4]
D[3]
IE
APCSEL
read/write
read/write
0010 0000b = 20h
D[2]
APCSEL
read/write
D[1]
APCSEL
read/write
D[0]
MODSEL
read/write
A2h
254 = FEh
Byte address
This register provides for control of the nominal APC setpoint and management of interrupts by the end-user. APCSEL[1:0]
select which of the APC setpoint registers, APCSET0, APCSET1, or APCSET2 are used as the nominal automatic power
control setpoint. Similarly, MODSEL[1:0] select which of MODSET0, MODSET1, or MODSET2 are used to select the
modulation level of the laser.
IE must be set for any host interrupts to occur via the /INT pin. If IE is set while /INT is asserted, /INT will be de-asserted
immediately.
PORS is always set high by any power-on reset event. If PORM is high, the power-on event will also generate a host interrupt.
PORS will be cleared to zero and the interrupt output de-asserted when USRCTL is read by the host.
If PORM is set following the setting of PORS, PORS will remain set, and /INT will be asserted immediately. /INT will not be deasserted until USRCTL is read by the host.
PORM, IE, APCSEL, and MODSEL are non-volatile and will be maintained through power and reset cycles.
Bit(s)
D[7]
D[6]
PORM
Function
Operation
Reserved
Always write as zero; reads undefined.
Power-on interrupt mask
1 = POR interrupts mask enabled
0 = POR interrupts mask disabled
D[5]
PORS
Power-on interrupt flag
1 = POR interrupt occurred
0 = No POR interrupt
D[4]
IE
D[3:2]
APCSEL
Global interrupt enable
1 = Host interrupts are enabled
0 = Host interrupts are disabled
Selects APC setpoint register
00 = APCSET0
01 = APCSET1
10 = APCSET2
11 = Reserved
D[1:0]
MODSEL
Selects Modulation setpoint register
00 = MODSET0
01 = MODSET1
10 = MODSET2
11 = Reserved
RESETOUT
D[7]
reserved
read-only
Default Value
Serial address
Byte address
July 2010
D[6]
reserved
read-only
D[5]
reserved
read-only
D[4]
reserved
read-only
D[3]
reserved
read-only
D[2]
D[1]
RESETOUT
RESETOUT
read/write
read/write
0000 0000b = 00h
D[0]
RESETOUT
read/write
A2h
255 = FFh
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Bit(s)
D[7-3]
D[2:0]
RESETOUT
Function
Operation
Reserved
Read-only; these bits always return 00000.
Controls the reset output at pin 2
(QGPO) when Reset mode is
selected (OEMCFG3-7 set to 1)
By default, these three bits are 000, and the QGPO output
is undriven.
If RESET mode is selected in OEMCFG3:
When the three bits are written to 111, QGPO’s open-drain
output will be driven low for 125 μs (typical), after which
QGPO reenters the undriven state.
The RESETOUT field is cleared from 111 to 000 22.5 ms
(typical) after the de-assertion edge of QGPO. Other values
of this delay may be selected in the TRSTCLR[2:0] field in
OEMCFG2.
If Reset mode in OEMCFG3 is not selected, these three
bits have no function.
OEM Configuration Register 0 (OEMCFG0)
D[7]
RST
write only
Default value
D[6]
QGPOS
read/write
D[5]
DFLT
read-only
Serial address
D[4]
D[3]
OE
MODREF
reserved
reserved
0000 0000b = 00h
D[2]
VAUX[2]
read/write
D[1]
VAUX[1]
read/write
D[0]
VAUX[0]
read/write
A6h
00 = 00h
Byte address
A write to OEMCFG0 will result in any A/D conversion in progress being aborted and the result discarded. The A/D will begin a
new conversion sequence once the write operation is complete.
All bits in OEMCFG0 are non-volatile except DFLT and RST. A valid OEM password is required for access to this register.
Bit(s)
D[7]
Function
RST
Operation
0 = no action; 1 = reset
Issuing a software reset by setting RST high is equivalent to
a full power cycle of the MIC3003.
D[6]
QGPOS
Determines the state of QGPO in
GPO mode
If OEMCFG3 bit 7 (QGPOM) is low, this bit determines
whether the QGPO output is high (undriven) or low (drivenopen-drain).
If QGPOM is high (Reset mode), this bit has no function
D[5]
DFLT
Diode fault flag.
1 = diode fault; 0 = OK.
D[4]
OE
Output enable for SHDN, VMOD,
and VBIAS.
1 = enabled; 0 = hi-Z
D[3]
MODREF
Selects whether VMOD is
referenced to ground or VDD.
1 = VDD; 0 = GND
D[2:0]
VAUX[2:0]
Selects the voltage reported in
VINh:VINl.
000 = VIN
001 = VDDA
010 = VBIAS
011 = VMOD
100 = APCDAC
101 = MODDAC
110 = FLTDAC
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MIC3003GFL
OEM Configuration Register 1 (OEMCFG1)
D[7]
INV
read/write
Default value
D[6]
GAIN
read/write
D[5]
BIASREF
read/write
Serial address
D[4]
D[3]
RFB[2]
RFB[1]
read/write
read/write
0000 0010b = 02h
D[2]
RFB[0]
read/write
D[1]
SRCE
read/write
D[0]
SPOL
read/write
A6h
1 = 01h
Byte address
A write to OEMCFG1 will result in any A/D conversion in progress being aborted and the result discarded. The A/D will begin a
new conversion sequence once the write operation is complete.
All bits in OEMCFG1 are non-volatile and will be maintained through power and reset cycles. A valid OEM password is
required for access to this register.
Bit(s)
D[7]
D[6]
D[5]
D[4:2]
INV
GAIN
BIASREF
RFB[2:0]
Function
Operation
Inverts the APC op-amp inputs.
When low, the BIAS DAC output is
connected to the “+”input and FB is
connected to the “–” input of the op
amp. Set low to use the APC
feedback loop.
0 = emitter follower (no inversion);
Sets the feedback voltage range by
changing the APCDAC output
swing; 0-VREF for optical feedback,
0-VREF/4 for electrical feedback.
1 = VREF/4 full scale;
Selects whether FB and VMPD are
referenced to ground or VDD and
selects feedback resistor termination
voltage (VDDA or GNDA).
1 = VDD; 0 = GNDA
Selects internal feedback resistance.
Resistors will be terminated to VDDA
or GNDA according to BIASREF.
000 = ∞
1 = common emitter (inverted); read/write; non-volatile.
0 = VREF full scale
If this bit is set to 0, bit 1 should be set to 1
If this bit is set to 1, bit 1 should be set to 0
001 = 800 Ω
010 = 1.6kΩ
011 = 3.2kΩ
100 = 6.4kΩ
101 = 12.8kΩ
110 = 25.6kΩ
111 = 51.2kΩ
D[1]
SRCE
VBIAS source or sink drive.
1 = source (NPN): bit 5 should be set to 0.
0 = sink (PNP): bit 5 should be set to 1.
D[0]
July 2010
SPOL
Polarity of the shutdown output,
SHDN, when active.
1 = SHDN is active-high
0 = SHDN is active-low
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MIC3003GFL
OEM Configuration Register 2 (OEMCFG2)
D[7]
SMBADR[3]
read/write
D[6]
SMBADR[2]
read/write
D[5]
SMBADR[1]
read/write
Default value
D[4]
D[3]
D[2]
D[1]
SMBADR[0]
TRSTCLR[2] TRSTCLR[1]
read/write
read/write
read/write
read/write
1010 0010b = xxh (device address = 1010 xxxxb)
Serial address
This value is the basis for using A0 h, A2 h, A4 h, and A6 h as the names of
the different device address spaces of the MIC3003.
A6h
Byte address
2 = 02h
D[0]
TRSTCLR[0]
read/write
Caution: Changes to SMBADR take effect immediately. Any accesses following a write to SMBADR must be to the newly
programmed serial bus address.
A valid OEM password is required for access to this register. This register is non-volatile and will be maintained through power
and reset cycles.
Function
Operation
D[7:4]
Bit(s)
SMBADR[3:0]
Most significant four bits of the
serial bus device address
Writes take effect immediately.
D[3:0]
TRSTCLR[2:0]
Set the delay between QGPO and
the clearing of RESETOUT
These three bits set the delay between the de-assertion
edge of the QGPO output in Reset mode and the
subsequent clearing of the three RESETOUT bits in the
RESETOUT Register:
000: Zero delay
001: 17.5 ms typical
010: 22.5 ms typical (default)
011: 27.0 ms typical
100: 45 ms typical
Minimum and maximum values may be found by adding
tolerances of -10% and +10% to the above values.
If Reset mode is not selected, these bits have no function.
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MIC3003GFL
APC Setpoint 0, 1, and 2 (APCSET0, APCSET1, APCSET2)
Automatic Power Control Setpoint
D[7]
read/write
D[6]
read/write
D[5]
read/write
Default value for all three bytes
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
APCSET0: 3 = 03h
Byte addresses
APCSET1: 4 = 04h
APCSET2: 5 = 05h
When the APC is on, the eight-bit signed integer compensation value corresponding to the current temperature is taken from
the BIASLUT look-up table, added to the selected APCSET (0, 1, or 2) register and loaded into the VBIAS DAC.
If DAC Calibration mode is selected in OEMCAL0, a write to any one of the three APCSETn registers will cause the VBIAS DAC
to be updated immediately. DAC Calibration mode disables the output of the BIASLUT lookup table, so the unmodified
APCSETn register value propagates directly to the DAC.
The eight-bit value presented to the VBIAS DAC is always available for read back in the APCDAC register.
A valid OEM password is required for access to these registers. These registers are non-volatile and will be maintained through
power and reset cycles.
Modulation Setpoint 0, 1, and 2 (MODSET0, MODSET1, and MODSET2)
Nominal VMOD Setpoint
D[7]
read/write
D[6]
read/write
Default value for all three bytes
Serial address
Byte address
D[5]
read/write
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
MODSET0: 6 = 06h
MODSET1: 30 = 1Eh
MODSET2: 31 = 1Fh
When the APC is on, the eight-bit signed integer compensation value corresponding to the current temperature is taken from
the MODLUT look-up table, added to the selected MODSET (0, 1, or 2) register and loaded into the VMOD DAC.
If DAC Calibration mode is selected in OEMCAL0, a write to any one of the three MODSETn registers will cause the VMOD DAC
to be updated immediately. DAC Calibration mode disables the output of the MODLUT lookup table, so the unmodified
MODSETn register value propagates directly to the DAC.
The eight-bit value presented to the VMOD DAC is always available for read back in the MODDAC register.
A valid OEM password is required for access to these registers. These registers are non-volatile and will be maintained through
power and reset cycles.
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MIC3003GFL
IBIAS Fault Threshold (IBFLT)
Bias Current Fault Threshold
D[7]
read/write
D[6]
read/write
D[5]
read/write
Default value
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
7 = 07h
Byte address
When the Fault Comparator is running, the eight-bit signed integer compensation value corresponding to the current
temperature is taken from the IFTLUT look-up table, added to IBFLT, and used for comparison with the laser bias current value
for fault generation. Faults are generated if the bias current value exceeds the compensated (LUT offset) IBFLT register
contents.
If DAC Calibration mode is selected in OEMCAL0, the output of the IFTLUT lookup table is disabled, so the unmodified IBFLT
register value propagates directly to the Fault Comparator DAC.
A valid OEM password is required for access to these registers. These registers are non-volatile and will be maintained through
power and reset cycles.
Transmit Power Fault Threshold (TXFLT)
D[7]
read/write
D[6]
read/write
D[5]
read/write
Default value
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
8 = 08h
Byte address
When the Fault Comparator is running the TXFLT register value is used for comparison with the transmit power value for fault
generation. Faults are generated if the transmit power exceeds the TXFLT register contents.
A valid OEM password is required for access to this register. This register is non-volatile and will be maintained through power
and reset cycles.
Loss-Of-Signal Threshold (LOSFLT)
D[7]
read/write
Default value
Serial address
Byte address
D[6]
read/write
D[5]
read/write
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
9 = 09h
When the Fault Comparator is running, a fault is generated if the received power is lower than the LOSFLT value set in this
register.
A valid OEM password is required for access to this register. This register is non-volatile and will be maintained through power
and reset cycles.
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MIC3003GFL
Fault Suppression Timer (FLTTMR)
Fault Suppression Interval in Increments of 0.5 ms
D[7]
read/write
D[6]
read/write
D[5]
read/write
Default value
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
10 = 0Ah
Byte address
Saturation faults are suppressed for a time, tFLTTMR, following laser turn-on. This avoids nuisance tripping while the APC loop
starts up. The length of this interval is (FLTTMR x 0.5 ms), typical. A value of zero will result in no fault suppression.
A valid OEM password is required for access to this register. This register is non-volatile and will be maintained through power
and reset cycles.
Fault Mask (FLTMSK)
D[7]
OEMIM
read/write
Default value
D[6]
POHE
read/write
D[4]
reserved
D[5]
reserved
D[3]
SATMSK
read/write
D[2]
TXMSK
read/write
D[1]
IAMSK
read/write
D[0]
DFMSK
read/write
0000 0000b = 00h
Serial address
A6h
11 = 0Bh
Byte address
A valid OEM password is required for access to this register. This register is non-volatile and will be maintained through power
and reset cycles.
Bit
D[7]
OEMIM
Function
Operation
OEM interrupt mask
1 = Interrupts are masked
0 = Interrupts are enabled
This bit is similar to the IE (Global Interrupt Enable) bit in the
User Control Register. The /INT output can only be asserted
if IE is high and OEMIM is low.
D[6]
POHE
OEM Power-on Hour Meter enable
1 = Power-on Hour Meter enabled
D[5:4]
D[5:4]
Reserved
Always write as zero; reads undefined
D[3]
SATMSK
APC saturation fault mask
1 = masked; 0 = enabled
D[2]
TXMSK
High TX optical power fault mask
1 = masked; 0 = enabled
D[1]
IAMSK
High bias current high fault mask
1 = masked; 0 = enabled
D[0]
DFMSK
Diode fault mask
1 = masked; 0 = enabled
0 = Power-on Hour Meter disabled
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MIC3003GFL
OEM Password Setting (OEMPWSET)
D[7]
read/write
D[6]
read/write
D[5]
read/write
Default value for all bytes
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
12 - 15 = 0Ch - 0Fh
Byte addresses
This four-byte field is the password required for access to the OEM area of the MIC3003’s memory and registers. This field is
compared to the four-byte OEMPW field at serial address A2h. If the two fields match, access is allowed to the OEM areas of
the MIC3003 non-volatile memory at serial addresses A4h and A6h.
The OEM password may be set by writing the new value into OEMPWSET. The new password will not take effect until after a
power-on reset occurs or a warm reset is performed using the RST bit in OEMCFG0. This allows the new password to be
verified before it takes effect.
These registers are non-volatile and will be maintained through power and reset cycles. A valid OEM password is required for
access to this register.
Byte
Weight
3
OEM Password, Most Significant Byte
2
OEM Password, 2nd Most Significant Byte
1
OEM Password, 2nd Least Significant Byte
0
OEM Password, Least Significant Byte
OEM Calibration 0 (OEMCAL0)
D[7]
reserved
read-only
Default value
Serial address
Byte address
D[6]
FLTDIS
read/write
D[5]
FSPIN
read/write
D[4]
D[3]
WRINH
APCCAL
read/write
read/write
0000 0000b = 00h
D[2]
reserved
read-only
D[1]
reserved
read-only
D[0]
FRCOPS
read/write
A6h
16 = 10h
A valid OEM password is required for access to this register. This register is volatile and will not keep its value through power
cycles.
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Bit
D[7]
D[6]
FLTDIS
Function
Operation
Reserved
Always write as zero; reads undefined.
Fault Comparator disable
0 = Fault Comparator faults enabled
1 = Fault Comparator faults disabled
When FLTDIS is high, the Fault Comparator does not run,
and the following faults are not detected:
•
High IBIAS faults
•
High transmit power faults
•
Low receive power faults
If a fault condition was detected prior to the assertion of
FLTDIS, the fault flag will remain active until cleared, but
cannot be set again until the Fault Comparator is allowed
to run.
D[5]
D[4]
FSPIN
WRINH
Fault Comparator “spin-on-channel” mode
select; do not enable ADC and FC spinon-channel modes simultaneously.
0 = Normal Fault Comparator operation
Inhibit NVRAM write cycles.
0 = Normal NVRAM operation
1 = Force the Fault Comparator to spin on one channel
When the Fault Comparator spins on just one channel
(selected via OEMCAL1[1:0]), the two channels not being
examined will not, of course, respond to fault conditions.
1 = Inhibit NVRAM writes
When WRINH is high, writes to the MIC3003’s internal
memory do not occur. Registers that are non-volatile are
written with the new value, but will not retain that value
through a power cycle, since the NVRAM backing storage
has not been modified.
D[3]
APCCAL
Selects APC DAC calibration mode DACs may be controlled directly.
0 = Normal mode
1 = DAC calibration mode.
When DAC calibration mode is enabled, the temperature
compensation lookup tables are disabled, so the DACs
are presented with the values written into their
corresponding registers.
D[2:1]
D[0]
July 2010
FRCOPS
Reserved
Always write as zeros; reads undefined.
Forces outputs for board-level or systemlevel testing
0 = Normal operation
1 = Force outputs for testing: The following outputs are
driven to their active states:
62
•
TXFAULT (active polarity set in OEMCFG5)
•
/INT (only driven if the OEMIM bit is clear in
FLTMSK)
•
RXLOS (active polarity and RXLOS selection are
set in OEMCFG6)
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OEM Calibration 1 (OEMCAL1)
D[6]
ADSTP
read/write
D[7]
reserved
read-only
Default value
D[5]
ADIDL
read-only
D[4]
ONESHOT
read/write
D[3]
ADSPIN
read/write
D[2]
SPIN[2]
read/write
D[1]
SPIN[1]
read/write
D[0]
SPIN[0]
read/write
0000 0000b = 00h
Serial address
A6h
Byte address
17 = 11h
A valid OEM password is required for access to this register. This register is volatile and will not keep its value through power
cycles.
Bit
D[7]
D[6]
ADSTP
Function
Operation
Reserved
Always write as zero; reads undefined.
Stop ADC: Halts the analog to digital
converter
0 = ADC in normal operation
1 = ADC stopped
When ADSTP is set, the five-channel ADC halts and no
new ADC results are computed. Existing result registers
are not changed.
In addition, no new temperature compensation is applied
to the APC loop and fault parameters, and no
comparisons of the ADC results against the alarm and
warning limits is performed.
D[5]
ADIDL
ADC idle flag
0 = ADC is busy
1 = ADC is idle
ADIDL may be used in conjunction with ONESHOT to
determine when the single ADC conversion is complete.
After ONESHOT is set, the ADC runs until completion
and then halts. Software may poll ADIDL to detect this
completion before interrofating the result.
D[4]
ONESHOT
Triggers one-shot A/D conversion cycle
0 = Normal ADC operation
1 = ADC one-shot mode
Setting ONESHOT high starts the ADC and causes it to
stop after the next conversion is complete. After the
conversion, the ADC remains stopped until ONESHOT is
set low.
Multiple single ADC conversions may be executed by
repeatedly writing one to ONESHOT.
D[3]
D[2:0]
ADSPIN
SPIN[2:0]
Selects ADC spin-on-channel mode; do
not enable ADC and FC spin-on-channel
modes simultaneously
0 = Normal ADC operation
ADC and Fault Comparator (FC) channel
select for spin-on-channel mode; do not
enable ADC and FC spin-on-channel
modes simultaneously
ADC:
1 = ADC spin-on-channel
000 = temperature
001 = voltage
010 = VILD
011 = VMPD
100 = VRX
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MIC3003GFL
LUT Index (LUTINDX)
D[7]
D[6]
D[5]
read-only
read-only
read-only
Default value (before the first set of 16
temperature measurements has been
accumulated)
Serial address
D[4]
read-only
D[3]
read-only
D[2]
read-only
D[1]
read-only
D[0]
read-only
0000 0000b = 00h
A6h
Byte address
18 = 12h
The look-up table index is derived from the current temperature measurement as follows:
INDEX = TAVG / 2
where TAVG is the current average temperature, averaged over a set of 16 samples. This register allows the current table index
to be read by the host. The appropriate table base address must be added to LUTINDX to form a complete table index in
physical memory.
A valid OEM password is required for access to this register.
OEM Configuration 3 (OEMCFG3)
D[7]
QGPOM
read/write
Default value
Serial address
Byte address
D[6]
TXFPOL
read/write
D[5]
GPOD
read/write
D[4]
GPOM
read/write
D[3]
GPOC
read/write
D[2]
TXFINM
read/write
D[1]
LOSDIS
read/write
D[0]
INTCAL
read/write
0000 1000b = 08h
A6h
19 = 13h
This register is non-volatile and will be maintained through power and reset cycles. A valid OEM password is required for access
to this register.
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Bit
Function
Operation
D[7]
QGPOM
QGPO pin function select
0: GPO (general purpose output)
D[6]
TXFPOL
TXFIN active polarity select; a fault is
indicated when TXFIN = TXFPOL
0 = The TXFIN input is active-low
1: Reset output
1 = The TXFIN input is active-high
This bit is ignored if TXFINM = 0
D[5]
GPOD
GPO output drive
0 = GPO output is open-drain
1 = GPO output is push-pull
This bit is ignored if GPOM = 0
D[4]
GPOM
GPO/RRSOUT pin mode select
0 = RRSOUT output
D[3]
GPOC
GPO output control
0 = Set the GPO pin low
1 = GPO output
1 = Set the GPO pin high
This bit is ignored if GPOM = 0
D[2]
TXFINM
SHDN/TXFIN pin mode select
0 = SHDN output
1 = TXFIN input
D[1]
LOSDIS
RXLOS comparator and output disable
0 = RXLOS fault enabled, and the RXLOS output is enabled
for normal operation
1 = RXLOS fault disabled; also, the RXLOS output is
disabled, and will remain low
D[0]
INTCAL
Calibration mode select
0 = External calibration mode
1 = Internal calibration(the MIC3003’s ALU applies slope and
offset coefficients to the ALU results as necessary)
BIAS DAC Setting (APCDAC)
Current VBIAS Setting
D[7]
read-only
Default value
Serial address
Byte address
D[6]
read-only
D[5]
read-only
D[4]
read-only
D[3]
read-only
D[2]
read-only
D[1]
read-only
D[0]
read-only
0000 0000b = 00h
A6h
20 = 14h
This register reflects (reads back) the value being sent to the BIAS DAC (APCSET0, APCSET1, or APCSET2 whichever is
selected, with temperature compensation applied).
A valid OEM password is required for access to this register.
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Modulation DAC Setting (MODDAC)
Current VMOD Setting
D[7]
read-only
Default value
D[6]
read-only
D[5]
read-only
D[4]
read-only
D[3]
read-only
D[2]
read-only
D[1]
read-only
D[0]
read-only
0000 0000b = 00h
Serial address
A6h
21 = 15h
Byte address
This register reflects (reads back) the value set in the being sent to the modulation DAC (MODSET0, MODSET1, or MODSET2
whichever is selected, with temperature compensation applied).
A valid OEM password is required for access to this register.
OEM Readback Register (OEMRD)
D[6]
KILL_LASER
read-only
D[7]
Reserved
read-only
Default value
D[5]
RXP_FLT
Read-only
Serial address
D[3]
D[4]
APCSAT
INT
read-only
read-only
0000 0000b = 00h
D[2]
IBFLT
read-only
D[1]
TXFLT
read-only
D[0]
RRSOUT
read-only
A6h
22 = 16h
Byte address
This register reflects (reads back) the status of the bits corresponding to the parameters defined below.
A valid OEM password is required for access to this register.
Bit
D[7]
D[6]
KILL_LASER
D[5]
RXP_FLT
Function
Operation
Reserved
Always reads as a zero
State of the internal laser disable
signal
0: The MIC3003 is disabling the laser
Registered Fault Comparator
detection of a receive power
fault
0: No Fault Comparator receive power fault
1: The laser is enabled to operate
1: The Fault Comparator has detected a receive power fault
D[4]
INT
Mirrors state of /INT but activehigh
1 = The interrupt is asserted
D[3]
APCSAT
Registered APC saturation fault
1 = APC saturation fault detected
0 = No pending interrupt.
0 = Normal operation.
D[2]
D[1]
D[0]
July 2010
IBFLT
TXFLT
TRSOUT
Registered Fault Comparator
detection of an IBIAS fault
1 = IBIAS fault detected
Registered Fault Comparator
detection of a transmit power
fault
1 = Registered transmit power fault
State of the rate select output
pin, TRSOUT
1 = high; 0 = low
0 = Normal operation
0 = normal operation
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Signal Detect Threshold (LOSFLTn)
D[7]
read/write
Default value
D[6]
read/write
D[5]
read/write
Serial address
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
23 = 17h
Byte address
This eight-bit register works in conjunction with the LOSFLT register to provide hysteresis and control the operation of the loss of
signal comparator. The comparator’s output, RXLOS, is asserted when the input on VRX falls below the level in LOSFLT. The
output will then be de-asserted when the VRX signal rises above the level in LOSFLTn.
The input signal is subject to scaling by the RXPOT. If the LOS comparator is disabled, i.e., LOSDIS = 1, this register is ignored.
A valid OEM password is required for access to this register. This register is non-volatile and will be maintained through power
and reset cycles.
RX EEPOT Tap Selection (RXPOT)
D[7]
reserved
read-only
Default value
D[6]
reserved
read-only
D[5]
reserved
read-only
Serial address
D[3]
D[4]
RXPOT[3]
RXPOT[4]
read/write
read/write
0000 0000b = 00h
D[2]
RXPOT[2]
read/write
D[1]
RXPOT[1]
read/write
D[0]
RXPOT[0]
read/write
A6h
24 = 18h
Byte address
This register is non-volatile and will be maintained through power and reset cycles. A valid OEM password is required for access
to these registers.
Bit(s)
Function
Operation
D[7:5]
Reserved
Reserved. Always write as zero; reads return zeros.
D[4:0]
RXPOT tap selection:
Adjust gain of the receive power measurement:
00000 = No divider action
00001 = 31/32
00010 = 30/32
•
•
•
11110 = 2/32
11111 = 1/32
OEM Configuration 4 (OEMCFG4)
D[7]
TXF_WRN
read/write
Default value
Serial address
Byte address
D[6]
TXF_ALM
read/write
D[5]
LAT_WRN
read/write
D[3]
D[4]
ISTART[3]
LAT_ALM
read/write
read/write
0000 0000b = 00h
D[2]
ISTART[2]
read/write
D[1]
ISTART[1]
read/write
D[0]
ISTART[0]
read/write
A6h
25 = 19h
This register is non-volatile and will be maintained through power and reset cycles. A valid OEM password is required for
access to these registers.
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Bit(s)
Function
D[7]
TXF_WRN
Operation
Allows warnings to assert
TXFAULT
0: Warnings do not assert TXFAULT
1: Warnings assert TXFAULT
The RXPWR low warning flag does not assert TXFAULT
D[6]
TXF_ALM
Allows alarms to assert
TXFAULT
0: Alarms do not assert TXFAULT
1: Alarms assert TXFAULT
The RXPWR low alarm flag does not assert TXFAULT
D[5]
LAT_WRN
0: Warnings flags are latched. They are cleared by reading
the register or toggling TXDISABLE.
Warning latch
1: Warnings flags are not latched., i.e. they are set and reset
with the warning condition. The flags are also cleared by
reading the register or toggling TXDISABLE.
D[4]
LAT_ALM
0: Alarms flags are latched. They are cleared by reading the
register or toggling TXDISABLE.
Alarm latch
1: Alarms flags are not latched., i.e. they are set and reset
with alarm condition. The flags are also cleared by reading
the register or toggling TXDISABLE.
D[3:0]
ISTART[3:0]
ISTART current level selection.
ISTART current level selection:
0000 = No ISTART current
0001 - 1111 = 0.375 mA x ISTART[[3:0]
ISTART is used to speed up the laser start-up after a fault
occurs. The charging current of the compensation capacitor
starts from ISTART instead of ramping up from 0.
OEM Configuration 5 (OEMCFG5)
D[7]
read/write
Default value
Serial address
Byte address
D[6]
read/write
D[5]
read/write
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
26 = 1Ah
This register is non-volatile and will be maintained through power and reset cycles. A valid OEM password is required for access
to these registers.
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Bit(s)
Function
Operation
D[7]
SHDN output enable / disable
0: SHDN is enabled. TXFAULT will trigger the SHDN output
1: SHDN is disabled. TXFAULT has no effect on the SHDN output
This applies when pin 12 is set as the SHDN output
D[6]
Lookup table temperature
offset control
0: The temperature result used for the LUT access averaging algorithm does
not have the offset coefficient applied
1: The temperature result used for the LUT access averaging algorithm is
offset by the signed 6-bit (.5 C resolution) offset coefficient.
D[5]
D[4]
Temperature result register
offset control
0: The temperature result register does not have the offset coefficient applied
Polarity of TXFAULT
0: TXFAULT is active-high
1: The temperature result register is offset by the signed 6-bit (.5 C resolution)
offset coefficient.
1: TXFAULT is active-low
D[3]
SMBus multipart support
0: Multipart mode off
1: Multipart mode on
D[2]
OEM password location
0: A6h: 120-123 (78h-7Bh)
1: A6h: 123-126 (7Bh-7Eh)
D[1]
SMBUS timeout enable /
disable
0: SMBUS timeout enabled
1: SMBUS timeout disabled
OEM Configuration 6 (OEMCFG6)
D[7]
read/write
Default value
Serial address
Byte address
D[6]
read/write
D[5]
read/write
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
27 = 1Bh
This register is non-volatile and will be maintained through power and reset cycles. A valid OEM password is required for access
to these registers.
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MIC3003GFL
Bit(s)
Function
Operation
D[7]
A0h space access control
0: A0h space is used according to SFF-8472
1: A0h space does not respond to any access request. SMBus transactions to
A0h receive a NACK response.
D[6:5]
RXPWR Linearization Intervals
00: Temperature-based coefficient selection
01: Programmable delimiters
10: Hard coded delimiters
11: Reserved
Options 01 and 10 partition the receive power result range into eight regions,
each of which has its own slope and offset coefficients. The delimiters identify
the region boundaries within the 12-bit receive power range of results, and
may be either hard-coded (10) or programmable (01).
Use of hard-coded delimiters frees up extra A6 memory space for scratchpad
use.
D[4]
TXDISABLE debounce enable
/ disable
0: TXDISABLE is not debounced
1: TXDISABLE is debounced. Glitches less than 5 ms are rejected.
Set this bit to 1 if a mechanical switch is used for TXDISABLE. Set to 0 for
normal operation to assure compliance to the SFP MSA.
D[3]
0: The RXLOS output is low for normal operation and high with a loss of signal
condition.
RXLOS Polarity
1: The RXLOS output is high for normal operation (signal detected) and low
with a loss of signal (no signal detected) condition.
D[2]
RXLOS/TRSOUT Select
0: RXLOS is selected for output
1: TRRSOUT is selected for output
D[1]
Temperature resolution
D[0]
TXFAULT clear mode
0: Temperature is measured to a resolution of 1 ºC (eight-bit resolution)
1: Temperature is measured to a resolution of 0.5 ºC (nine-bit resolution)
0: TXFAULT remains set until TXDISABLE is toggled
1: TXFAULT is in continuous mode and follows the state of the faults
In continuous mode, the fault conditions asserting TXFAULT are not registered
and turn on and off According to the MIC3003’s operation.
Power-On Hour Meter Data (POHDATA)
D[7]
D[6]
D[5]
read/write
read/write
read/write
Default values for all bytes when the MIC3003
is shipped
Serial address
Byte addresses
D[4]
D[3]
read/write
read/write
0000 0000b = 00h
D[2]
read/write
D[1]
read/write
D[0]
read/write
A6h
32 – 34 and 36 - 38 = 20h - 22h and 24h - 26h
These registers are used for backing up the POH result during power cycles. At power-up, the POH meter selects the larger of
the two values as the initial count. Incremental results are stored in alternate register pairs. The power-on hour meter may be
reset or preset by writing to these registers.
These registers are not typically intended to be used by the OEM or end user. The current value of the power-on hours meter
may be read from the POHh and POHl registers.
If it is necessary to preset the power-on hours meter to a specific value, please consult the factory for the exact format to be
written to the POHDATA registers.
These registers are non-volatile and will be maintained through power and reset cycles. A valid OEM password is required for
access to these registers.
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Byte
Weight
3
POHA, high-byte
2
POHA, low-byte
1
POHB, high-byte
0
POHB, low-byte
OEM Scratchpad Registers (SCRATCHn)
Default value
0000 0000b = 00h
Serial address
A6h
Byte addresses
136 - 207 (88 - CFh)
208 - 221 (D0 - DDh): This area is part of the OEM scratch pad only if the hardcoded delimiters option for receive power linearization is used.
222 - 250 (DE - FAh)
The scratchpad registers are general-purpose non-volatile memory locations. They can be freely read from and written to any
time the MIC3003 is in OEM mode.
RX Power Coefficient Look-up Table (RXLUTn)
Default values
Serial address
Offset coefficients are set to a default value of zero
Slope coefficients are set to a default value of 1.0
A6h
Byte addresses
40 - 71 = 28h - 47h
These registers hold the receive power slope and offset coefficients used to calibrate the MIC3003’s ADC receive power result
in internal calibration mode.
These registers are non-volatile and will be maintained through power and reset cycles. A valid OEM password is required for
access to these registers.
A6 Address
Bytes
40 (28h)
RXSLP0h
RX slope 0, high byte
41 (29h)
RXSLP0l
RX slope 0, low byte
42 (2Ah)
RXOFF0h
RX offset 0, high byte
43 (2Bh)
RXOFF0l
RX offset 0, low byte
44 (2Ch)
RXSLP1h
RX slope 1, high byte
45 (2Dh)
RXSLP1l
RX slope 1, low byte
46 (2Eh)
RXOFF1h
RX offset 1, high byte
47 (2Fh)
RXOFF1l
•
•
•
RXSLP7h
RX offset 1, low byte
•
•
•
RX slope 7, high byte
69 (45h)
RXSLP7l
RX slope 7, low byte
70 (46h)
RXOFF7h
RX offset 7, high byte
71 (47h)
RXOFF7l
RX offset 7, low byte
68 (44h)
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Calibration Constants (CALCOEFn)
Default values
Serial address
Offset coefficients are set to a default value of zero
Slope coefficients are set to a default value of 1.0
A6h
Byte addresses
74 - 87 = 4Ah - 57h
These registers hold the slope and offset coefficients used to calibrate the MIC3003’s ADC results in internal calibration mode.
Note that the temperature offset is also used in external calibration mode; but this can be disabled in OEMCFG5 (or by setting
the offset coefficient to zero).
These registers are non-volatile and will be maintained through power and reset cycles. A valid OEM password is required for
access to these registers.
A6
Address
Bytes
Definition
74 (4Ah)
TOFFh
Temperature offset (six-bit signed offset, .5 C resolution)
75 (4Bh)
TOFF0l
Not used
76 (4Ch)
VSLP0h
Voltage slope, high byte
77 (4Dh)
VSLP0l
Voltage slope, low byte
78 (4Eh)
VOFFh
Voltage offset, high byte
79 (4Fh)
VOFF0l
Voltage offset, low byte
80 (50h)
ISLP0h
Bias current slope, high byte
81 (51h)
ISLP0l
Bias current slope, low byte
82 (52h)
IOFFh
Bias current offset, high byte
83 (53h)
IOFF0l
Bias current offset, low byte
84 (54h)
TXSLPh
TX Power slope, high byte
85 (55h)
TXSLPl
TX Power slope, low byte
86 (56h)
TXOFFh
TX Power offset, high byte
87 (57h)
TXOFFl
TX Power offset, low byte
Manufacturer ID Register (MFG_ID)
Identifies Micrel as the manufacturer of the device. Always returns 2Ah
D[7]
read-only
Default value
D[6]
read-only
Serial address
Byte address
D[5]
read-only
D[4]
D[3]
read-only
read-only
0010 1010b = 2Ah
D[2]
read-only
D[1]
read-only
D[0]
read-only
A6h
254 = FEh
The value in this register, in combination with the DEV_ID register, serves to identify the MIC3003 and its revision number to
software.
This register is read-only.
Bit(s)
Function
Operation
D[7:0]
Identifies Micrel as the manufacturer of the device. Always
returns 2Ah.
Read-only. Always returns Ah
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MIC3003GFL
Device ID Register (DEV_ID)
D[7]
read-only
D[6]
read-only
D[5]
read-only
D[4]
read-only
D[3]
read-only
MIC3003 Device ID
always reads 0 at D[7-6] and 11 at D[5-4]
Default value
0011 XXXXb = 3Xh
Serial address
Byte address
D[2]
read-only
D[1]
read-only
D[0]
read-only
Die Revision
A6h
255 = FFh
The value in this register, in combination with the MFG_ID register, serve to identify the MIC3003 and its revision number to
software. This register is read-only.
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MIC3003GFL
Package Information
24-Pin MLF® (MLF-24)
MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA
TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http:/www.micrel.com
The information furnished by Micrel in this data sheet is believed to be accurate and reliable. However, no responsibility is assumed by Micrel for its
use. Micrel reserves the right to change circuitry and specifications at any time without notification to the customer.
Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product
can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical
implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user.
A Purchaser’s use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to
fully indemnify Micrel for any damages resulting from such use or sale.
© 2010 Micrel, Incorporated.
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