JDSU JSH-42L3AD3-5G

.
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Features
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International Class 1 laser safety certified
RoHS directive compliant (lead-free)
4x,2x,1x (ANSI) Fibre Channel [1] compliant
Gigabit Ethernet Compatible
Long wavelength (LW)
JSH-42L3AD3-5 max. distance of 5 km
JSH-42L3AD3-20 max. distance of 20 km
Digital Diagnostic Monitoring Interface SFF8472 Compliant [5]
EMI Emissions below Class B
Single +3.3 V Power Supply
-15°C ambient to 85°C case operation
UL and CSA approved
Optional interrupt on alarms and warnings
Applications
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•
•
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Fibre Channel
Ethernet Networking
Client/Server environments
Distributed multi-processing
Fault tolerant applications
Visualization, real-time video, collaboration
Channel extenders, data storage, archiving
Data acquisition
Description
These JDSU SFPs are integrated fiber optic transceivers that provide a high-speed serial link at a signaling rate up to 4.25 Gb/s. They conform to the
American National Standards Institute’s (ANSI)
Fibre Channel, and SFF-8472 specifications.
The JSH-42L3AD3-5 supports a maximum fiber distance of 5 km and is available with blue color identification or gray color identificaiton (JSH-42L3AD35G). The JSH-42L3AD3-20 supports a maximum
fiber distance of 20 km. These transceivers operate
on singlemode fiber only.
The transceiver is ideally suited for Fibre Channel
applications which include point to point links as well
as Fibre Channel Arbitrated Loop (FC-AL). It can
also be used for other serial applications where high
data rates are required. This specification applies to
a hot-pluggable (SFP) module which is an electrical
surface-mount connector assembly.
The transceiver features a microprocessor with
imbedded non-volatile RAM. Vital product data is
stored in the NVRAM and several optical and electri-
cal characteristics of the transceiver are computed
“Real-Time” with the results written to memory. This
data can all be accessed by a two-wire serial interface at the SFP connector.
Encoded (8B/10B) [3], [4], serial differential signals
traverse the connector interfacing the transceiver to
the host card. The serial data modulates the laser
and is sent out over the outgoing fiber of a duplex
cable.
The transceiver is a certified Class 1 laser safe
product. The optical power levels, under normal
operation, are at eye safe levels. Optical fiber cables
can be connected and disconnected without shutting
off the laser transmitter.
The transceiver is also compliant with the RoHS
Directive from the European Union - Directive
2002/95/EC on the Restriction Of use of certain
Hazardous Substances. The largest change with
optical transceivers comes with the removal of all
lead-based parts and soldering. Now it is a lead-free
part.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 1 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Package Outline
Pin Definitions
Pin #
Pin Name
Type
Sequence
Pin #
Pin Name
Type
Sequence
Ground
1
11
Rx Ground
Ground
1
Signal Out
3
12
-Rx_DAT
Data Out
3
Signal In
3
13
+Rx_DAT
Data Out
3
1
Tx Ground
2
Tx_Fault
3
Tx_Disable
4
MOD_DEF(2)
Input/Output
3
14
Rx Ground
Ground
1
5
MOD_DEF(1)
Input/Output
3
15
Rx Power
Power
2
6
MOD_DEF(0)
Input/Output
3
16
Tx Power
Power
2
7
Reserved
Signal In
3
17
Tx Ground
Ground
1
8
Rx_LOS
Signal Out
3
18
+Tx_DAT
Data In
3
9
Reserved
Signal In
3
19
-Tx_DAT
Data In
3
10
Rx Ground
Ground
1
20
Tx Ground
Ground
1
Laser Safety Compliance
The JDSU transceiver is a CLASS 1 LASER PRODUCT as defined by the international standard IEC
60825-1, Am.2 (2001). The product also complies
with U.S.A. regulations for Class 1 products contained in 21 CFR 1040.10 and 1040.11. Laser emissions from Class 1 laser products are not
considered hazardous when operated according to
product specifications. Operating the product with a
power supply voltage exceeding 5.0 volts may compromise the reliability of the product, and could
result in laser emissions exceeding Class 1 limits
identified in IEC 60825-1, Am.2 (2001); under these
circumstances, viewing the transmitter port with optical aides (i.e., eye loupes) should be avoided.
ESD Notice
It is advised that normal static precautions be taken
in the handling and assembly of the transceiver to
prevent damage and/or degradation which may be
introduced by electrostatic discharge.
JDSU Product Specification 21111542-001
Page 2 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Ordering Information
Part Number1
Signaling Rate
Wavelength
Distance Supported2
Laser Type
FP (Fabry-Perot)
JSH-42L3AD3-5
1.0625 Gb/s, 2.125 Gb/s, or 4.25 Gb/s
1310 nm
5 km
JSH-42L3AD3-5G
1.0625 Gb/s, 2.125 Gb/s, or 4.25 Gb/s
1310 nm
5 km
FP (Fabry-Perot)
JSH-42L3AD3-20
1.0625 Gb/s, 2.125 Gb/s, or 4.25 Gb/s
1310 nm
20 km
DFB (Distributed Feedback)
1. All transceivers come with a Blue bail cover, except those that end with a "5G". "5G" come with a Gray bail cover.
2. When used with two JDSU transceivers.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 3 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Block Diagram
Optical
Electrical
Receive Section
Optical
Input
+Rx_DAT
Post-amp
and
Photoreceiver
-Rx_DAT
LOS Detect
Rx_LOS
Application_Select(0,1)
Mux
Average RX
Power Monitor
TX
Power
Monitor
10b ADC
μP
TX_FLT
Soft
as
Interrupt DSBL
Two-Wire
Interface
Temp Indicator
NVRAM
Vcc
MOD_DEF(0)
MOD_DEF(1)
MOD_DEF(2)
Laser
Bias
Monitor
Laser
Output
Laser
AC Modulation
+Tx_DAT
-Tx_DAT
Back Facet
Feedback
DC Drive
and
Safety Control
Fault
Sense
Tx_Disable
Tx_Fault
Transmit Section
JDSU Product Specification 21111542-001
Page 4 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Transmit Section
The input, an AC coupled differential data stream from the host, enters the AC Modulation section of the laser
driver circuitry where it modulates the output optical intensity of a semiconductor laser. The DC Drive circuit
incorporates an automatic power control (APC) loop which maintains the laser at the correct preset power
level. In addition, safety circuits in the DC Drive will shut off the laser, or guarantee safe launch power if a
fault is detected. The transceiver provides the AC coupling for the +Tx/-Tx lines. No AC coupling capacitors
are required on the host card for proper operation. There are two outputs from the transmitter section that
deliver signals proportional to the average transmitted optical power and also the laser average bias current.
These signals are digitized and processed within the transceiver for the Digital Diagnostic Monitoring feature.
Receive Section
The incoming modulated optical signal is converted to an electrical signal by the photoreceiver. This electrical
signal is then amplified and converted to a differential serial output data stream and delivered to the host. A
signal strength detector indicates whether light is present or not at the input to the photoreceiver. This signal
is provided to the host as a loss-of-signal (Rx_LOS) status line. The transceiver provides the AC coupling for
the +Rx/-Rx lines. No AC coupling capacitors are required on the host card for proper operation. There is an
output from the pre-amplifier in the photoreceiver that is proportional to the average optical power incident on
the photodiode. This signal is digitized and processed within the transceiver as part of the Digital Diagnostic
Monitoring feature.
Digital Diagnostic Monitoring
The digital diagnostic monitoring feature is compliant with document SFF-8472, “Digital Diagnostic Monitoring
Interface for Optical Transceivers” [5]. In addition to transmitted optical power, laser-bias current and received
optical power, there are also sensors for transceiver temperature and supply voltage which are all multiplexed
to the analog-to-digital converter. After the signals are digitized, they are processed and compared to alarm
levels for the optional alarm features and interrupts. The real-time values of each monitored parameter can
be read and used for evaluating the status of the link. Also, the alarm/warning bits can be used to provide
transceiver status or enable an interrupt notification. A user-writable non-volatile RAM scratch space for customer use is limited to 100,000 write cycles.
Optional Monitor TX_FAULT Alarm/Warning Interrupt
The transceiver provides programmable Alarm/Warning Interrupt Enable bits. They are used by the transceiver to generate a TX_FAULT signal usable as an interrupt to the host for an alarm/warning condition. This
is an extension to the polling architecture of SFF-8472 and allows for interrupt driven host microcode. For a
complete description see section “Vendor Specific Digital Diagnostic Monitor TX_FAULT Alarm/Warning
Interrupt” on page 37.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 5 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Input Signal Definitions
Levels for the signals described in this section are listed in Transmit Signal Interface on page 16 and Control
Electrical Interface on page 17.
Tx_DAT
A differential serial data stream is presented to the transceiver for transmission onto an optical fiber by modulating the optical output intensity of the laser.
Tx_Disable
When high (logic one), the Tx_Disable signal turns off the power to both the AC and DC laser driver circuits.
It will also reset a laser fault if one should happen. When low (logic zero), the laser will be turned on within
1ms unless a Tx_Fault condition exists.
When this signal is asserted, the laser monitoring function will report low power and low bias current. The
alarm/warning flags for these quantities will also become active. Additionally, the Tx_Disable indicator, bit 7 in
byte 110 of the DDM page will become active. See Monitor Data Table 4 on page 35.
t_reset
> 10 μs
Tx_Disable
Transmitter optical
signal
t_off
< 10 μs
t_on
< 1 ms
Application_Select (0:1)
The transceiver provides multiple application selection capability in accordance with the SFF-8079+ and SFF8089[6]. The Application_Select pins control internal settings which configure the transceiver for optimal performance at a given data rate. The Application_Select(0) was previously labelled Rate Select and
Application_Select(1) was an Rx Ground. Full software control based on the application select tables in the
A0 page is also available. These pins are compatible with previous implementations of SFP transceivers.
Data Rate
4xFC (4.250 Gb/s)
2xFC (2.125 Gb/s)
1xFC (1.0625 Gb/s)
GbE (1.250 Gb/s)
Application_Select(0)
0 or 1 or float
0 or 1 or float
0 or 1 or float
Not applicable
Application_Select(1)
0 or 1 or float
0 or 1 or float
0 or 1 or float
Not Applicable
JDSU Product Specification 21111542-001
Page 6 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Output Signal Definitions
Levels for the signals described in this section are listed in Receive Signal Interface (from transceiver to host)
on page 17 and Control Electrical Interface on page 17.
Rx_DAT
The incoming optical signal is converted and repowered as a differential serial data stream. The Receive Signal Interface (from transceiver to host) table on page 17 gives the voltage levels and timing characteristics for
the Rx_DAT signals.
Rx_LOS
The Receive Loss of Signal line is high (logic one) when the incoming modulated light intensity is below that
required to guarantee the correct operation of the link. Normally, this only occurs when either the link is
unplugged or the companion transceiver is turned off. This signal is normally used by the system for diagnostic purposes.
This signal has an open drain TTL driver. A pull up resistor is required on the host side of the SFF connector.
The recommended value for this resistor is 10 kΩ.
Tx_Fault
Upon sensing an improper power level in the laser or any other potentially unsafe condition, the SFF sets this
signal high and turns off the laser. The Tx_Fault signal can be reset with the Tx_Disable line.
The laser is turned off within 100 μs as shown in the Transmitter Fault Detection timing diagram below.
This signal has an open drain TTL driver. A pull up resistor is required on the host side of the SFF connector.
The recommended value for this resistor is 10 kΩ.
Tx_Fault can also become active if the alarm/warning enable control bits are set within the 0xA2page. For a
complete description see section “Vendor Specific Digital Diagnostic Monitor TX_FAULT Alarm/Warning
Interrupt” on page 37.
Output Signal Timings
Receive Loss of Signal Detection
Optical Signal
Signal Removed
Transmitter Fault Detection
Occurrence of
transmitter
safety fault
Tx_Fault
Rx_LOS
Optical
Power
t_loss_on
<100μs
t_loss_off
<100μs
t_fault
<100μs
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 7 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
MOD_DEF(0:2)
A two-wire serial interface is used to access two 256-byte memory spaces that describe some of the capabilities, standard interfaces, manufacturer, optical monitor levels, alarms and other information relevant to the
product. Some of this space is protected and some is user writable. Also some of the space is non-volatile so
that information is retained during unpowered conditions. Tables describing the specific addresses and values of the memory space are included in Two-Wire Interface Timing Specifications on page 23 and on page
31. Operation of the two-wire interface is described in Two-Wire Protocol for Serial ID and Digital Diagnostic
Monitoring Information on page 11. Signal timings necessary for proper operation of the Serial ID function are
shown in Two-Wire Interface Timing Specifications on page 23.
The two-wire interface requires both a serial clock (SCL) and serial data I/O (SDA) connections. These signals are required to have pull up resistors on the host board to the 3.3V supplying the transceiver (4.7 kΩ is
the recommended value; however, a smaller value may be needed in order to meet the Serial ID’s rise and
fall time requirements). The following list and figure show the necessary connections from an interface to a
SFF to ensure the capability of reading the Serial ID data.
MOD_DEF(0): Logic Low
MOD_DEF(1): SCL
MOD_DEF(2): SDA
The serial clock (SCL) and the serial data (SDA) lines appear as NC to the host system upon initial power up.
Expected Connections to SFF MOD_DEF Pins
MOD_DEF(0)
SCL
MOD_DEF(1)
SDA
MOD_DEF(2)
Interface
Host
SFF
JDSU Product Specification 21111542-001
Page 8 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Operation
Initialization Timings
Tx_Disable De asserted
Tx_Disable Asserted
Vcc > 3.0V
Vcc > 3.0V
Tx_Fault
Tx_Fault
Tx_Disable
1
Tx_Disable
0
Optical Transmit
Signal
Optical Transmit
Signal
t_init
< 300 ms
Not Monitoring
t_init < 300 ms
Monitoring
Not Monitoring
Monitoring
Two-Wire Interface
Capable
Two-Wire Interface
Capable
t_serial <= 250 ms
t_serial <= 250 ms
Two-Wire Interface Capable
The transceiver will be capable of responding to a start sequence on the Two-Wire interface (see “Two-Wire
Protocol for Serial ID and Digital Diagnostic Monitoring Information” on page 11) 250 ms after application of
3.0 volts, or greater up to maximum, at the voltage inputs of the transceiver. If a start sequence is transmitted
by the host prior to 250 ms after power is good, the transceiver may not acknowledge the sequence.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 9 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Resetting a Laser Fault
Resetting a laser fault by toggling the Tx_Disable input will permit the transceiver to attempt to power on the
laser following a fault condition.
Fault Condition Recovery Timings
Successful Recovery from a
Transmitter Safety Fault
Unsuccessful Recovery from a
Transmitter Safety Fault
Occurrence
of transmitter
safety fault
Occurrence
of transmitter
safety fault
Tx_Fault
Tx_Fault
Tx_Disable
Tx_Disable
Optical
Power
Optical
Power
t_reset
> 10 μs
*only if the fault is transient
t_init*
< 300 ms
t_reset
> 10 μs
*only if the fault is transient
t_fault
< 100 μs
t_init*
< 300 ms
JDSU Product Specification 21111542-001
Page 10 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Two-Wire Protocol for Serial ID and Digital Diagnostic Monitoring Information
Product specific information is stored in the device and is accessible via a standard two-wire interface. Some
of the data is non-volatile and some is updated real time with data that characterizes critical conditions of the
transceiver. While most registers are read only, some registers can be written by the customer for use as
scratch space or to set interrupt enables or clear interrupt indicators.
There are two data addresses which can be used to access two different sets of data. The page address
0b1010000X is used for the set of Serial ID data and the page address 0b1010001X is used for the set of Digital Diagnostic Monitoring information.
Critical timings for communicating to the module on the two-wire interface are shown in Two-Wire Interface
Figure 8 on page 14. For more information on the Serial ID protocol, see Two-Wire Interface Timing Specifications on page 23.
Two-wire Data Read
To read data from the device, the following sequence must occur on the Two-wire interface (refer to TwoWire Interface Figure 2 on page 13, Two-Wire Interface Figure 3 on page 13, and Two-Wire Interface Figure
4 on page 13 throughout these steps):
1. Send a start signal to the module.
A start signal is presented by toggling the data line from high to low while the clock is high (see Two-Wire
Interface Figure 2 on page 13).
2. Send the write data sequence.
The write data sequence consists of the bits 0b10100000 for the Serial ID data or 0b10100010 for the
Digital Diagnostic Monitoring information.
3. Receive an acknowledge signal.
One zero bit is the acknowledge signal.
Once this sequence has been acknowledged, the user will send the memory address to start reading
from.
4. Send the address of the first byte to be read during the subsequent sequence.
5. Receive an acknowledge signal.
6. Send a start signal.
7. Send the read data sequence.
The read data sequence consists of the bits 0b10100001 for the Serial ID data or 0b10100011 for the
Digital Diagnostic Monitoring information.
8. Receive an acknowledge signal.
Once this sequence has acknowledged, the user will begin receiving data bytes.
9. Receive a data byte.
10. Send an acknowledge signal to receive the next, consecutive data byte, or send a no-acknowledge signal
followed by a stop signal to stop receiving data.
A stop signal is presented by toggling the data line from low to high while the clock is high (see Two-Wire
Interface Figure 2 on page 13).
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 11 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Two-wire Data Write
To write data to the Digital Diagnostic Monitoring data address of the device (writes are not allowed to the
Serial ID data address), the following sequence must occur on the Two-wire interface (refer to Two-Wire
Interface Figure 1 on page 13, Two-Wire Interface Figure 2 on page 13, and Two-Wire Interface Figure 3 on
page 13 throughout these steps):
1. Send a start signal to the module.
A start signal is presented by toggling the data line from high to low while the clock is high (see Two-Wire
Interface Figure 2 on page 13).
2. Send the data write sequence.
The write data sequence consists of the bits 0b10100000 for the Serial ID data or 0b10100010 for the
Digital Diagnostic Monitoring information.
3. Receive an acknowledge signal.
One zero bit is the acknowledge signal.
4. Send the address of the first byte to be written during the subsequent sequence.
Valid byte addresses are 0b01101110 for one byte, and byte addresses 0b10000000 thorough
0b11110111.
5. Receive an acknowledge signal.
6. Send a data byte.
7. Receive an acknowledge signal.
8. Send the next, consecutive data byte (reference Two-Wire Interface Figure 7 on page 14), or send a stop
signal to stop sending data (reference Two-Wire Interface Figure 6 on page 14).
A stop signal is presented by toggling the data line from low to high while the clock is high (see Two-Wire
Interface Figure 2 on page 13).
JDSU Product Specification 21111542-001
Page 12 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Two-Wire Interface Figure 1 Data transfer on the Two-wire interface
Acknowlegement signal from slave
SDA
MSB
SCL
1
2
8
3
9
2
1
8
ACK
9
ACK
start
stop
Two-Wire Interface Figure 2 Start and Stop TIming
SDA
SCL
STOP
START
Two-Wire Interface Figure 3 Set Data Address Sequence for Read Timing
Acknowledge from SFF
Acknowledge from SFF
SDA
1
0
1
0
0
0
0
0
A
C
K
0
0
0
0
0
0
0
0
A
C
K
SCL
0
S
T
A
R
T
Data address to start reading
data from. (Addr. 0 in this
example, 0 through 255 available)
Byte entered to allow the
user to set the starting
address for a Serial ID data read.
S
T
A
R
T
Two-Wire Interface Figure 4 Read Data Sequence Timing
Acknowledge from SFF
SDA
1
0
1
0
0
0
0
1
The data line is normally high. It will remain high
until an Acknowledge or a Stop command is sent.
A
C
1
0
0
1
1
0
1
0
K
SCL
S
Byte entered to allow the
T
user to start reading data.
A
R (Sequence continued from Serial ID Figure 4.)
T
continued from Figure 3
An example data word.
(9A in this example)
S
T
O
P
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 13 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Two-Wire Interface Figure 5 Set Data Address Sequence for Write Timing
Acknowledge from SFF
Acknowledge from SFF
SDA
1
0
1
0
0
0
1
0
A
C
K
1
0
0
0
0
0
0
0
A
C
K
SCL
S
T
A
R
T
Byte entered to allow the
user to set the starting
address for an Optical
Monitoring data write.
Data address to start writing
data to. (Address 128 in this
example, 0 through 255 available)
Two-Wire Interface Figure 6 Write Data (Single-Byte) Sequence Timing
Acknowledge from SFF
SDA
0
1
1
0
0
1
0
1
Note: The first byte after a start condition must always be
the address byte for the transceiver (either A0 or A2 with
the low order bit indicating write/read) or there will not be
an acknowledge.
A
C
K
SCL
S
T
A
R
T
S
T
O
P
An example data word.
(65 in this example)
(Continued from Two-Wire Interface Figure 6.)
Two-Wire Interface Figure 7 Write Data (Multi-Byte) Sequence Timing
Acknowledge from SFF
Acknowledge from SFF
SDA
0
1
1
0
0
1
0
1
A
C
K
1
0
0
1
1
0
1
A
C
K
SCL
S
T
A
R
T
An example data word.
(65 in this example)
(Continued from Two-Wire Interface Figure 6.)
An example data word.
(9A in this example)
S
T
O
P
Two-Wire Interface Figure 8 Critical Timings
Parameters are defined in Two-Wire Interface Timing Specifications on page 23.
tLOW
SCL
tR
tHIGH
tF
tLOW
tHD.DAT
tSU.STA
tSU.DAT
tHD.STA
tSU.STO
SDA IN
tAA
tDH
tBUF
SDA OUT
JDSU Product Specification 21111542-001
Page 14 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Absolute Maximum Ratings
Symbol
TS
Parameter
Storage Temperature
RHS
Relative Humidity–Storage
VCC
Supply Voltage
VI
TTL DC Input Voltage
Min.
Typical
Max.
Unit
Notes
-40
85
°C
1
0
90
%
1, 2
-0.5
5.0
V
1
0
VCC + 0.7
V
1
100,000
cycles
Non-Volatile Write Cycles
1. Stresses listed may be applied one at a time without causing permanent damage. Exposure to these values for extended periods
may affect reliability. Specification Compliance is only defined within Specified Operating Conditions.
2. Non-condensing environment.
Specified Operating Conditions
Symbol
Parameter
Min.
Typical
Max.
Unit
TOP
Operating Temperature
-15
851
°C
TOP
Operating Temperature2
-40
-15
°C
VCC
Supply Voltage (+/- 10%)
3.0
3.6
V
90
%
Typical
Max.
Unit
200
300
mA
240
300
mA
RHOP
Relative Humidity-Operating
3.3
5
1. Case temperature
2. Compatible operation (BER<10-12)
Power Supply Interface
Symbol
IVCC
IVCC
Parameter
VCC Current (combined Tx and Rx)
JSH-42L3AD3-20
VCC Current (combined Tx and Rx)
JSH-42L3AD3-5
Min
P
Total Power Dissipation (combined Tx and Rx)
JSH-42L3AD3-20
650
10001
mW
P
Total Power Dissipation (combined Tx and Rx)
JSH-42L3AD3-5
800
10002
mW
100
mV (pk-pk)
Ripple & Noise
1. At 3.3 volts
2. At 3.3 volts
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 15 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Transmit Signal Interface (from host to transceiver)
Symbol
Parameter
Min
Max.
Unit
Notes
Vo
Amplitude
300
2400
mV
1
DJelec-xmit
Deterministic Jitter
0.14
UI
2
TJelec-xmt
Total Jitter
0.26
UI
2
ps
3
Rise/Fall
SDD11
60
Differential Skew
20
ps
Input Return Loss
-11
dB
4
Return Loss
-9
dB
4
1. At 100Ω, differential peak-to-peak, the figure below shows the simplified circuit schematic for the transceiver high-speed differential input lines. The input data lines have AC coupling capacitors. The capacitors are not required on the host card.
VDD
+Tx_DAT
50 Ω
50 Ω
4.65 kΩ
2 pF
-Tx_DAT
2. Deterministic jitter (DJ) and total jitter (TJ) values are measured according to the methods defined in [2]. Jitter values at the output
of a transmitter or receiver section assume worst case jitter values at its respective input. [1UI(Unit Interval)=235.3 ps at 4.25Gb/s]
3. Rise and fall times are measured from 20 - 80%, 100Ω differential.
4. At 2.125 GHz
JDSU Product Specification 21111542-001
Page 16 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Receive Signal Interface (from transceiver to host)
Symbol
Parameter
Min
Max.
Unit
Note(s)
Vo
Amplitude
600
1600
mV
1,2
DJelec-rcv
Deterministic Jitter
0.39
UI
3
TJelec-rcv
Total Jitter
0.64
UI
3
Common Mode Voltage (rms)
30
mV
SDD22
Return Loss
-9
dB
4
SCC22
Return Loss
-7
dB
4
1. At 100Ω, differential peak-to-peak, the figure below shows the simplified circuit schematic for the transceiver high-speed differential
output lines. The output data lines have AC coupling capacitors. The capacitors are not required on the host card.
Rx_VDD
50 Ω
50 Ω
+Rx_DAT
-Rx_DAT
...
Rx_Gnd
2. 600 mV Min for "AD3" part numbers.
3. Deterministic jitter (DJ) and total jitter (TJ) values are measured according to the methods defined in [2]. Jitter values at the output
of a transmitter or receiver section assume worst case jitter values at its respective input. [1UI(Unit Interval)=235.3 ps at 4.25Gb/s].
4. at 2.125 GHz
Control Electrical Interface
Symbol
Parameter
Min
Max.
Unit
0.0
0.50
V
VDD - 0.5
VDD + 0.3
V
0.0
0.8
V
2.0
VDD + 0.3
V
0.0
VDD x 0.3
V
VDD x 0.7
VDD + 0.5
V
Note(s)
Voltage Levels
VOL
TTL Output (from transceiver)
VOH
VIL
1
TTL Input (to transceiver)
VIH
VIL
2
Serial ID SCL and SDA lines
VIH
1
Timing Characteristics
1.
2.
3.
4.
5.
6.
A 4.7k - 10kΩ pull-up resistor to VDD on host is required.
A 10 kΩ pull-up resistor to VDD is present on the transceiver.
See Tx_Disable on page 6 and Operation on page 9 for timing relationships.
See “Two-Wire Interface Capable” on page 9
See Operation on page 9.
See Rx_LOS on page 7 for timing relations.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 17 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Control Electrical Interface
Symbol
Parameter
Min
Max.
Unit
Note(s)
t_off
Tx_Disable Assert time
10
μs
3
t_on
Tx_Disable De-assert time
1
ms
3
μs
3
t_reset
Tx_Disable (time to start reset)
t_serial
Two-Wire Initialization Time
250
ms
4
Initialization Time
300
ms
5
t_fault
Tx_Fault Assert Time
100
μs
5
t_loss_on
Rx_LOS Assert Delay
100
μs
6
t_loss_off
Rx_LOS De-Assert Delay
100
μs
6
t_init
1.
2.
3.
4.
5.
6.
10
A 4.7k - 10kΩ pull-up resistor to VDD on host is required.
A 10 kΩ pull-up resistor to VDD is present on the transceiver.
See Tx_Disable on page 6 and Operation on page 9 for timing relationships.
See “Two-Wire Interface Capable” on page 9
See Operation on page 9.
See Rx_LOS on page 7 for timing relations.
JDSU Product Specification 21111542-001
Page 18 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Optical Receiver Specifications
Symbol
λ
RL
Parameter
Operating Wavelength
Min
Typical
1270
Max.
Unit
1365
nm
Notes
Return Loss of Receiver
12
OMAop
OMA operational range - 4.25 Gb/s
29
10
2000
μW (pk-pk)
1, 2
OMAop
OMA operational range - 2.125 Gb/s
15
6
2000
μW (pk-pk)
1, 2
OMAop
OMA operational range - 1.0625 Gb/s
15
6
2000
μW (pk-pk)
1, 2
Poff
Rx_LOS Assert Level
-30
-20
dBm (avg)
3
Pon
Rx_LOS De-Assert (negate) Level
-20.5
dBm (avg)
3
5
dB (optical)
3
5000
MHz
Rx_LOS Hysteresis
BWRx
Receiver Electrical 3 dB Upper Cutoff Frequency
0.5
dB
2
1. The minimum and maximum values of the average received power in dBm give the input power range to maintain a
BER < 10-12 when the data is sampled in the center of the receiver eye. These values take into account power penalties caused by
the use of a laser transmitter with a worst-case combination of spectral width, extinction ratio and pulse shape characteristics.
2. Optical Modulation Amplitude (OMA) is defined as the difference in optical power between a logic level one and a logic level zero.
The Optical Modulation Amplitude is defined in terms of average optical power (PAVG in μW) and extinction ratio (ER) as given by
OMA=2PAVG((ER-1)/(ER+1)). The extinction ratio, defined as the ratio of the average optical power (in μW) in a logic level one to
the average optical power in a logic level zero measured under fully modulated conditions in the presence of worst case reflections, must be the absolute (unit less linear) ratio and not expressed in dB. For example, the specified OMA at 4.25 Gb/s is equivalent to an average power of -17.3 dBm at an ER of 9 dB. At 1.0625 Gb/s and 2.125 Gb/s, the specified OMA is equivalent to an
average power of -20.2 dBm at an ER of 9 dB. Typical values below the minimum specification indicate margin beyond the specification.
3. The Rx_LOS has hysteresis to minimize “chatter” on the output line. In principle, hysteresis alone does not guarantee chatter-free
operation. The transceiver, however, presents an Rx_LOS line without chatter, where chatter is defined as a transient response
having a voltage level of greater than 0.5 volts (in the case of going from the negate level to the assert level) and of any duration
that can be sensed by the host logic.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 19 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Optical Transmitter Specifications
Symbol
Parameter
Min
Typical
Max.
Unit
λC
Spectral Center Wavelength (JSH-42L3AD3-5)
1285
1350
nm
λC
Spectral Center Wavelength (JSH-42L3AD3-20)
1300
1325
nm
Δλ
Spectral Width (JSH-42L3AD3-5)
2.0
nm (rms)
Δλ
Spectral Width (JSH-42L3AD3-20)
0.2
nm (rms)
SMSR
Side Mode Supression Ratio (JSH-42L3AD3-20)
PT
Launched Optical Power
ER
Extinction Ratio
Trise/Tfall
Optical Rise/Fall Time
30
dB
-8.4
-1.0
6
(4.250 Gb/s)
Notes
dBm (avg)
1
dB
90
ps
2
OMA
Optical Modulation Amplitude (JSH-42L3AD3-5)
190
μW (pk-pk)
3
OMA
Optical Modulation Amplitude (JSH-42L3AD3-20)
290
μW (pk-pk)
3
RIN12
Relative Intensity Noise
dB/Hz
4
-118
1. Launched optical power is measured at the end of a two meter section of a singlemode fiber. The maximum and minimum of the allowed range of
average transmitter power coupled into the fiber are worst case values to account for manufacturing variances, drift due to temperature variations,
and aging effects. The minimum launched optical power specified assumes an infinite extinction ratio at the minimum specified OMA.
2. Optical transition time is the time interval required for the rising or falling edge of an optical pulse to transition between the 20% and 80% amplitudes relative to the logical 1 and 0 levels. This is measured through a 4th order Bessel -Thompson filter with 0.75 * Data Rate 3-dB bandwidth
and corrected to the full bandwidth value. Use of the 4G FC compliance filter results in an equivalent rise/fall time specification of 116 ps.
3. Optical Modulation Amplitude (OMA) is defined as the difference in optical power between a logic level one and a logic level zero. The Optical
Modulation Amplitude is defined in terms of average optical power (PAVG in μW) and extinction ratio (ER) as given by OMA=2PAVG((ER1)/(ER+1)). In this expression, the extinction ratio, the ratio of the average optical power (in μW) in a logic level one to the average optical power in
a logic level zero measured under fully modulated conditions in the presence of worst case reflections, must be the absolute (unit less linear) ratio
and not expressed in dB. The specified Optical Modulation Amplitude is equivalent to an average power of -7.3 dBm at an extinction ratio of 9 dB.
4. RIN12 is the laser noise, integrated over a specified bandwidth, measured relative to average optical power with 12dB return loss. See ANSI Fibre
Channel Specification Annex A.5.
JDSU Product Specification 21111542-001
Page 20 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Optical Cable and Connector Specifications
Symbol
Parameter
Min
Typical
Max.
Unit
Notes
9/125 μm Cable Specifications (Singlemode 1310nm)
L
Length - 4.25 Gb/s (JSH-42L3AD3-5)
2
5000
m
2
L
Length - 4.25 Gb/s (JSH-42L3AD3-20)
2
20000
m
2
L
Length - 2.125 Gb/s (JSH-42L3AD3-5)
2
11000
m
2
L
Length - 2.125 Gb/s (JSH-42L3AD3-20)
2
28000
m
2
L
Length - 1.0625 Gb/s (JSH-42L3AD3-5)
2
20000
m
2
L
Length - 1.0625 Gb/s (JSH-42L3AD3-20)
2
28000
m
2
μc
Attenuation @ λ = 1310 nm
0.3
0.35
dB/km
0.4
dB
1
dB
1
cycles
1
LC Optical Connector Specifications (Multimode)
μcon
Nominal Attenuation
0.2
σcon
Attenuation Standard Deviation
0.1
Connects/Disconnects
250
1. The optical interface connector dimensionally conforms to the industry standard LC type connector documented in [1]. A dual
keyed LC receptacle mechanically aligns the optical transmission fiber to the SFP.
2. Distance stated is when two JDSU transceivers are used, one at each end of the link.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 21 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Electrical Connector
Symbol
Parameter
Insertion/Removal Cycles
Max.
Unit
100
Cycles
Dust Plug / Aqueous Wash
A JDSU process/dust plug provided with the module must be in place for any dry-air cleaning processes. The
module cannot be immersed in any cleaning solvents nor withstand an aqueous wash. Only the process/dust
plug provided with the module is allowed. If the process/dust plug is not contaminated during non-installed
use, it may be re-used.
JDSU Product Specification 21111542-001
Page 22 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Two-Wire Interface Timing Specifications
Parameter
Symbol
Min
Max
Units
Notes
100
kHz
1
Clock Frequency
fSID
Clock Pulse Width Low
tLOW
4.7
μs
1
Clock Pulse Width High
tHIGH
4.0
μs
1
tAA
0.1
4.5
μs
1
250
ms
3
Clock Low to Data Out Valid
Initialization Time
tserial
Time the data line must be free before a new
transmission can start
tBUF
4.7
μs
1
Start Hold Time
tHD.STA
4.0
μs
1
Start Set-up Time
tSU.STA
4.7
μs
1
Data In Hold Time
tHD.DAT
0
μs
1
Data In Set-up Time
tSU.DAT
200
ns
1
Inputs Rise Time
tR
1.0
μs
1
Inputs Fall Time
tF
300
ns
1
Stop Set-up Time
Data Out Hold Time
Vdd Hold Time for User Write
tSU.STO
4.7
μs
1
tDH
100
ns
1
tVddH
25+(N x 10)
ms
2
1. See Two-Wire Interface Figure 8 on page 14 for timing relationships. See Two-Wire Protocol for Serial ID and Digital Diagnostic
Monitoring Information on page 11 for information on protocol.
2. The Vdd supply to the transceiver must remain valid for 25 + (N x 10) ms, where N is the number of bytes desired to write to the
scratch space (bytes 128-247 in 0xA2 address). For example: A single byte write will require 35 ms of valid supply voltage after the
Stop bit for that instruction is completed. A sequential multi-byte write of the entire 120 bytes into the user scratch space will require
the supply to remain valid for at least 1.23 s after the stop bit is completed.
3. The time from application of 3.0 V or greater Vdd supply at the transceiver voltage inputs to when the transceiver will be capable of
responding to a start sequence on the two-wire interface.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 23 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
SFF 8472 Monitored Values
Parameter
Min
Max
Units
Notes
Received Optical Power Meter Dynamic Range
-20
+1.0
dBm
1
Received Optical Power Meter Accuracy
-2.0
+2.0
dB
2,3
-9
-1.0
dBm
2
Transmitted Optical Power Meter Accuracy
-2.0
+2.0
dB
2
Laser Bias Current Meter Dynamic Range
4.0
90
mA
2
-0.90
+0.90
mA
2
2.8
4.5
V
2
-0.10
0.10
V
2
Transceiver Temperature Meter Dynamic Range
-40
100
°C
2
Transceiver Temperature Meter Accuracy
-3
+3
°C
2
Transmitted Optical Power Meter Dynamic Range
Laser Bias Current Meter Accuracy
Power Supply Voltage Meter Dynamic Range
Power Supply Voltage Meter Accuracy
1. Actual optical power incident on the receiver. This range, when coupled with the accuracy specified means that the power meter
can read from -18 dBm to +3 dBm when input optical power is in the range -16 dBm to +1 dBm.
2. When transceiver is operated within its specified temperature and power supply voltage dynamic operating ranges.
3. When optical input power is within the optical power meter specified dynamic operating range.
JDSU Product Specification 21111542-001
Page 24 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Two-Wire Interface Memory Map
Below is a summary of the transceiver memory map. The transceiver provides multiple application selection
capability in accordance with SFF-8079+[6]. Modifications to the memory map in support of this feature are to
be determined. Additional details can be found in the sections that follow.
Address 0xA0
Address 0xA2
See Monitor Data Table 1 on page 28
0
See Monitor Data Table 1 on page 33
0
Alarm and Warning Thresholds
(56 bytes)
See Monitor Data Table 2 on page 35
Serial ID Defined by SFP MSA
(96 bytes)
See Serial ID Table 1 on page 28
55
56
95
96
127
128
234
235
Vendor Specific (32 bytes)
Application Select Table (per
SFF-8079 and SFF-8089 MSAs)
JDS Uniphase Data
255
Calibration constants (40 bytes)
95
96 Real Time Diagnostic Interface
(24 bytes)
See Monitor Data Table 4 on page 36
119
120 Vendor Specific (8 bytes)
127
128
User Writable EEPROM
(120 bytes)
247
248
255
Tx_Fault Alarm, Warning interrupt
control. See detailed section on
page 37.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 25 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Serial ID Data Descriptions (Page/Device Address 0xA0)
All ID information is stored in eight-bit parameters addressed from 0x00 to 0x7F. All numeric information
fields have the lowest address in the memory space storing the highest order byte. The highest order bit is
always transmitted first. All numeric fields will be padded on the left with zeros. All character strings are
ordered with the first character to be displayed located in the lowest address of the memory space. All character strings will be padded on the right with ASCII spaces (0x20) to fill empty bytes.
Check Codes
The check codes contained within the identification data are one byte codes that can be used to verify that
the data in previous addresses is valid. CC_BASE check code is the lower eight bits of the sum of the contents of bytes 0-62. CC_EXT check code is the lower eight bits of the sum of the contents of bytes 64-94.
JDSU Product Specification 21111542-001
Page 26 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Serial ID Table 1 Data Fields - Page/Device Address 0xA0
Data
Address
Field
Size
(Bytes)
Value
(Hex)
Value
(Binary)
Value
(ASCII)
Name of Field
Description of Field
Base ID Fields
0
1
03
00000011
Identifier
1
1
04
00000100
Ext. Identifier
2
1
07
00000111
Connector
3
00
00000000
Reserved
4
00
00000000
SONET
5
00
00000000
SONET
00
00000000
7
12
00010010
8
0
00000000
9
01
00000001
Singlemode fiber
10
15
00010101
4G, 2G, 1G FC
6
Transceiver
Codes
8
SFP transceiver
Extended identifier of type of serial transceiver
LC connector
No GbE Compliance
Long Distance Longwave Laser
11
1
01
00000001
Encoding
8b/10b Encoding
12
1
2B
00101011
BR, nominal
13
1
00
00000000
Reserved
14
1
00000101
05 or 14 or
00010100
5 or 20
Fiber Length
(singlemode)
(km)
Link length supported for 9/125 μm fiber in units of km
15
1
00110010
32 or C8 or
11001000
50 or 200
Fiber Length
(singlemode)
(100m)
Link length supported for 9/125 μm fiber in units of 100 meters
16
1
00
00000000
Fiber Length
(50/125μm)
(10m)
Link length supported for 50/125 μm fiber in units of 10 meters
17
1
00
00000000
Fiber Length
(62.5/125μm)
(10m)
Link length supported for 62.5/125 μm fiber in units of 10
meters
18
1
00
00000000
Length
(coppper)
19
1
00
00000000
Reserved
Nominal bit rate in units of 100 Mb/s.
Link length supported for copper in units of meters
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 27 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Serial ID Table 1 Data Fields - Page/Device Address 0xA0
Data
Address
Field
Size
(Bytes)
20-35
36
37-39
Value
(Hex)
Value
(Binary)
Value
(ASCII)
4A
J
44
D
53
S
20
(space)
55
U
4E
N
49
I
50
P
48
H
41
A
53
S
45
E
20
(space)
20
(space)
20
(space)
20
(space)
16
1
3
Name of Field
Vendor name
00
00000000
00
00000000
01
00000001
9C
10011100
Description of Field
SFP transceiver vendor name (ASCII)
Reserved
Vendor OUI
SFP transceiver vendor IEEE company ID
JDSU Product Specification 21111542-001
Page 28 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Serial ID Table 1 Data Fields - Page/Device Address 0xA0
Data
Address
40-55
56-59
60-61
Field
Size
(Bytes)
16
Value
(Hex)
Value
(Binary)
Value
(ASCII)
4A
01001010 J
53
01010011 S
48
01001000 H
2D
00101101 -
34
00110100 4
32
00110010 2
4C
01010011 L
33
00110101 3
41
01000001 A
44
01000010 D
33
00110010 3
2D
00101101 -
35
00110101 5 or 2
20
00100000
20
00100000 (space)
20
00100000 (space)
20
00100000 (space)
20
00100000 (space)
20
00100000 (space)
20
00100000 (space)
05
00000101
1E
00011110
00
00000000
63
1
Part number provided by the SFP transceiver vendor (ASCII)
Vendor revision Revision level for part number provided by vendor (ASCII)
2
1
Vendor
Part Number
Description of Field
space, 0 or
G
4
62
Name of Field
Wavelength
Wavelength of the laser in nm with byte 60 as MSB. (1310 nm)
Reserved
CC_BASE
Check code for Base ID Fields (addresses 0 to 62)
Options
Tx_Disable, Tx_Fault, Loss of Signal all implemented
Extended ID Fields
64-65
00
00000000
1A
00011010
2
66
1
05
00000101
BR, maximum
Upper bit rate margin, units of percent (5%)
67
1
05
00000101
BR, minimum
Lower bit rate margin, units of percent (5%)
68-83
16
Vendor
Serial Number
Serial number provided by the vendor (ASCII)
84-91
8
Date Code
Vendor’s manufacturing date code
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 29 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Serial ID Table 1 Data Fields - Page/Device Address 0xA0
Data
Address
Field
Size
(Bytes)
Value
(Hex)
Value
(Binary)
92
1
68
01101000
Digital
Diagnostic
Options
DDM Implemented, Internally calibrated, Rx power measurement type is average power
93
1
F0
11110000
Enhanced
Options
Optional warning flags implemented, Soft Tx_Disable, Soft
Tx_Fault, Soft Rx_LOS
94
1
01
00000010
SFF-8472
Compliance
Includes functionality described in Rev 9.5 SFF-9472
95
1
CC_EXT
Check code for the Extended ID Fields (addresses 64-94)
Read Only
Vendor specific data, read only
Value
(ASCII)
Name of Field
Description of Field
Vendor Specific ID Fields
96-127
32
“MICROCODE
COPYRIGHT
2002
JDSU”
JDSU Product Specification 21111542-001
Page 30 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Application Select Tables
The Application Select Tables contain information that allows the host system to control internal settings
which configure the transceiver for optimal perfromance at a given data rate.
The different application codes are selected via byte 111 in the A2 page. To select one of the application
codes, bit 7 in byte 111 is set to 1 and bit 5:0 are set to the desired application table. The contents of the
Application codes are compliant to the Application_Select MSAs SFF-8079 and SFF-8089.
Application Select Table
Byte Address
Length (bytes)
Name of Field
Description
128
1
CC_APPS
Check code for the Application Select Table. The check
code is the low order 8 bits of the sum of the contents of all
the bytes from byte 129 to byte 255.
129
bits (7:6)
Reserved
129
bits (5:0)
AST Table Length, TL
130
2
Application Code 0
132
2
Application Code 1
134
2
Application Code 2
232
2
Application Code 52
A 6-bit binary number, TL, that specifies how many application table entries are defined in bytes 130 - 255 addresses.
TL is valid between 0 (one entry) and 51 (for a total of 52
entries).
JDSU Transceiver Data
Data Addresses
Field Size (Bytes)
235
4
239
4
243
4
247
4
251
4
Name of FIelds
Description
Digital Diagnostic Monitor Data Descriptions (Page/Device Address 0xA2)
The Monitor Data ID tables that follow describe the data contained in the 256 bytes of Page/Device Address
0xA2. Monitor Data Table 1 is a summary of all of the data fields in the Monitor Data section of the memory.
Monitor Data Table 2 on page 34 and Monitor Data Table 4 on page 35 provide more detailed translations of
data words for some of the data fields.
To guarantee coherency of the diagnostic monitoring data, the host is required to retrieve any multi-byte fields
from the diagnostic monitoring data structure by the use of a single multi-byte read sequence across the
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 31 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
serial interface.
Monitor Data Table 1 Data Fields Summary- Page/Device Address 0xA2
Byte
Address
Length
(Bytes)
0-55
56
Manufacturer’s preset alarm and warning threshold levels.
56-95
40
Polynomial constants for externally processing raw A/D digital values.
(default to Zero for Internally Calibrated parts, Serial ID Byte 92, Bit 5 set to one)
96-119
24
Real time diagnostic data, alarms, warnings and soft control bits.
120-127
8
128-247
120
248-255
8
Description of Fields
Vendor specific.
User writable non-volatile scratch space.
Tx_Fault Alarm/Warning Interrupt Contol Bits
Internal Calibration
This transceiver contains internally calibrated values such that the values should be interpreted as follows:
Temperature: The temperature data is the internal transceiver temperature. The temperature is represented
as a 16-bit signed twos complement value in increments of 1/256 °C. This yields a value from -128 to +128 °C
but is only valid if within the operating specifications of the transceiver. Temperature accuracy is +/- 3 °C.
Voltage: The voltage data will be calibrated to the internally measured Transmit VDD supply. The voltage is
represented as a 16-bit unsigned integer with the voltage equal to the full 16-bit decimal value (0 to
65535)*100 μV. This yields a total range of 0 to 6.55 volts but is only valid if within the operating specifications
of the transceiver. Accuracy is +/-3% of nominal voltage (3.3 +/- 0.10 V)
TX Bias: The TX Bias data is calibrated to reflect the average current biasing the laser diode. The TX Bias is
represented as a 16-bit unsigned integer with the current value equal to the full 16-bit decimal value (0 to
65535)*2 μA. This yields a total range of 0 to 131mA but is only valid if within the operating specifications of
the transceiver. Accuracy is +/-10% of nominal value over specified operating temperature and voltage.
TX Power: The TX Power data is calibrated to reflect the average power coupled into a nominal fiber [7]. The
accuracy takes into account the fiber to fiber variation and also calibration test equipment accuracies. The TX
Power is represented as a 16-bit unsigned integer with the power value equal to the full 16-bit decimal value
(0 to 65535)*0.1 μW. This yields a total range of 0 to 6.55 mW but is only valid if within the operating specifications of the transceiver. Data is not valid when the transmitter is disabled. Accuracy is +/-2 dB over specified operating voltage and temperature.
RX Power: RX Power data is calibrated to reflect the average optical power exiting the ferrule of a nominal
fiber[7]. The accuracy takes into account the fiber to fiber variation and also calibration test equipment accuracies. The RX Power is represented as a 16-bit unsigned integer with the power value equal to the full 16-bit
decimal value (0 to 65535)*0.1 μW. This yields a total range of 0 to 6.55 mW but is only valid if within the
operating specifications of the transceiver. Accuracy is +/- 2dB over specified operating voltage and temperature.
JDSU Product Specification 21111542-001
Page 32 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Digital Diagnostic Monitor Data Offsets
The Digital Diagnostic Monitor Data page is a single 256-byte page with regard to read and write access offsets. There are no mini-page sections within the 256-byte space. Contiguous, sequential accesses, without
modifying the offset, will cycle through offsets 0 to 255 then return to offset 0.
Digital Diagnostic Monitor Data Write Access
The Digital Diagnostic Monitor Data page contains an area defined as a user writable, non-volatile scratch
space, that can be written to by the user, and which will be non-volatile across power cycles and resets. This
space can be accessed sequentially and contiguously within the offsets defined for it (refer to Monitor Data
Table 1 on page 32). If during the course of a sequential, multi-byte write, the offset being written reaches the
end of the user writable space, the next byte of data will be a write attempt to the vendor specific area.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 33 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Monitor Data Table 2 Alarm and Warning Threshold Levels
Factory Programmed Value
In Units Specified by SFF8472 Standard
Byte
Address
Length
(Bytes)
0-1
2
Temp High Alarm
MSB at low address
0x5F00
95
2-3
2
Temp Low Alarm
MSB at low address
0xDD00
-35
4-5
2
Temp High Warning
MSB at low address
0x5A00
90
6-7
2
Temp Low Warning
MSB at low address
0xE200
-30
8-9
2
Voltage High Alarm
MSB at low address
0x8DCC
3.63 V
10-11
2
Voltage Low Alarm
MSB at low address
0x7404
2.97 V
12-13
2
Voltage High Warning
MSB at low address
0x8BD8
3.58 V
14-15
2
Voltage Low Warning
MSB at low address
0x75F8
3.02 V
16-17
2
Bias High Alarm
MSB at low address
0xA604
85.0 mA
18-19
2
Bias Low Alarm
MSB at low address
0x0BB8
6.0 mA
20-21
2
Bias High Warning
MSB at low address
0x9C40
80.0 mA
22-23
2
Bias Low Warning
MSB at low address
0x0FA0
8.0 mA
24-25
2
TX Power High Alarm
MSB at low address
0x1F07
0.7943 mW
-1 dBm
26-27
2
TX Power Low Alarm
MSB at low address
0x0630
0.1585 mW
-8.0 dBm
28-29
2
TX Power High Warning
MSB at low address
0x1BA7
0.7080 mW
-1.5 dBm
30-31
2
TX Power Low Warning
MSB at low address
0x07CB
0.1995 mW
-7.0 dBm
32-33
2
RX Power High Alarm
MSB at low address
0x1F07
0.7943 mW
-1.0 dBm
34-35
2
RX Power Low Alarm
MSB at low address
0x009E
0.0158 mW
-18.0 dBm
36-37
2
RX Power High Warning
MSB at low address
0x1BA8
0.7080 mW
-1.5 dBm
38-39
2
RX Power Low Warning
MSB at low address
0x00C7
0.0199 mW
-17 dBm
40-55
16
Reserved
.
Name
Byte Alignment
Factory Programmed
Equivalent Value
Monitor Data Table 3 Digital Diagnostic Check Sum Byte.
Byte
Address
Length
(Bytes)
95
1
Name
Checksum
Description of Fields
The lower eight bits of the sum of the contents of bytes 0-94.
JDSU Product Specification 21111542-001
Page 34 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Monitor Data Table 4 Diagnostic Data Values, Alarms, Warnings and Status Bits
Byte
Address
Bit
96-97
All
Temperature Value1
Internal Transceiver Temperature (MSB at low address)
98-99
All
Voltage Value1
TX VDD Voltage (MSB at low address)
100-101
All
TX Bias Value1
Laser Diode Average Current (MSB at low address)
102-103
All
TX Power Value1
Average Fiber Coupled Power (MSB at low address)
104-105
All
RX Power Value1
Average Received Power (MSB at low address)
106-109
All
Reserved
Reserved for future MSA monitored parameters.
110
7
TX Disable State
State of TX Disable input pin
110
6
Soft TX Disable
Read/Write bit that allows software disable of laser. Writing a ‘1’ disables
the laser. Default power value is ‘0’. This bit is internally OR’ed with the
hard TX_DISABLE pin value.
110
5
AS1 State
Digital state of AS1 input pin.
110
4
RX Rate Select AS0 State
Digital state of rate_select input pin.
110
3
Soft Rate Select
Not Applicable
110
2
TX Fault
State of TX Fault output pin.
110
1
LOS
Sate of LOS output pin.
110
0
Data Ready Bar1,2
Indicates transceiver has achieved power and Digital Diagnostic data is
ready to be read.
111
7:6
Control Mode
Not Applicable
111
5:0
Table Select (TS)
For soft application_select, a 6-bit binary number (TS) that represents the
sequence of the Application code in the AST. It is written by the host for
select module behavior.
112
7
Temp High Alarm 1,3
Set when internal temperature exceeds the bytes 0-1 level.
112
6
Temp Low Alarm 1,3
Set when internal temperature is below the bytes 2-3 level.
112
5
Voltage High Alarm 1,3
Set when TX VDD exceeds the bytes 8-9 level.
112
4
Voltage Low Alarm 1,3
Set when TX VDD is below the bytes 10-11 level.
112
3
TX Bias High Alarm 1,3
Set when Laser Diode Current exceeds the bytes 16-17 level.
Name
Description of Fields
1. The Digital Diagnostic Monitoring values and Alarm/Warning indicators will be set to zero, and Data Ready Bar will be set high, for
certain failure mechanisms within the transceiver that do not affect the link capability of the transceiver. Refer to Vendor Specific
Digital Diagnostic Monitor TX_FAULT Alarm/Warning Interrupt on page 37 for additional information on transceiver Digital Diagnostic Monitoring status.
2. The data ready bar bit is held high during module power up and prior to the first transceiver sampling of the monitored values. The
bit will be set low after each first successful sampling occurs and remain low until the transceiver looses power or a failure occurs.
The bit must be set low within 1 second of reaching a valid stable power supply level.
3. Bytes 112-119 contain a set of non-latched alarm and warning flags. Users can choose to read these values and use them to analyze the status of the transceiver as an alternative to decoding the real-time values in bytes 96-105. Alarm flags indicate levels that
are likely to be associated with link failures. Warning flags indicate levels that are outside of normal levels, but not necessarily
cause for immediate concern (could be used for end-of-life indicators).
4. The Vendor Specific area is further defined below in Vendor Specific Digital Diagnostic Monitor TX_FAULT Alarm/Warning Interrupt
on page 37.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 35 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Monitor Data Table 4 Diagnostic Data Values, Alarms, Warnings and Status Bits
Byte
Address
Bit
112
2
TX Bias Low Alarm 1,3
Set when Laser Diode Current is below the bytes 18-19 level.
112
1
TX Power High Alarm 1,3
Set when Avg. Fiber Coupled Power exceeds the bytes 24-25 level.
112
0
TX Power Low Alarm 1,3
Set when Avg. Fiber Coupled Power is below the bytes 26-27 level.
113
7
RX Power High Alarm 1,3
Set when Avg. Received Power exceeds the bytes 32-33 level.
113
6
RX Power Low Alarm 1,3
Set when Avg. Received Power is below the bytes 34-35 level.
113
5-0
Reserved
Reserved
114-115
All
Reserved
Reserved
116
7
Temp High Warning 1,3
Set when internal temperature exceeds the bytes 4-5 level.
116
6
Temp Low Warning1, 3
Set when internal temperature is below the bytes 6-7 level.
116
5
Voltage High Warning 1,3
Set when TX VDD exceeds the bytes 12-13 level.
116
4
Voltage Low Warning 1,3
Set when TX VDD is below the bytes 14-15 level.
116
3
TX Bias High Warning 1,3
Set when Laser Diode Current exceeds the bytes 20-21 level.
116
2
TX Bias Low Warning 1,3
Set when Laser Diode Current is below the bytes 22-23 level.
116
1
TX Power High Warning1, 3
Set when Avg. Fiber Coupled Power exceeds the bytes 28-29 level.
116
0
TX Power Low Warning 1,3
Set when Avg. Fiber Coupled Power is below the bytes 30-31 level.
117
7
RX Power High Warning 1,3
Set when Avg. Received Power exceeds the bytes 36-37 level.
117
6
RX Power Low Warning 1,3
Set when Avg. Received Power is below the bytes 38-39 level.
117
5-0
Reserved
Reserved
118-119
All
Reserved
120-127
All
Name
Vendor Specific
Description of Fields
Reserved
4
Vendor Specific
1. The Digital Diagnostic Monitoring values and Alarm/Warning indicators will be set to zero, and Data Ready Bar will be set high, for
certain failure mechanisms within the transceiver that do not affect the link capability of the transceiver. Refer to Vendor Specific
Digital Diagnostic Monitor TX_FAULT Alarm/Warning Interrupt on page 37 for additional information on transceiver Digital Diagnostic Monitoring status.
2. The data ready bar bit is held high during module power up and prior to the first transceiver sampling of the monitored values. The
bit will be set low after each first successful sampling occurs and remain low until the transceiver looses power or a failure occurs.
The bit must be set low within 1 second of reaching a valid stable power supply level.
3. Bytes 112-119 contain a set of non-latched alarm and warning flags. Users can choose to read these values and use them to analyze the status of the transceiver as an alternative to decoding the real-time values in bytes 96-105. Alarm flags indicate levels that
are likely to be associated with link failures. Warning flags indicate levels that are outside of normal levels, but not necessarily
cause for immediate concern (could be used for end-of-life indicators).
4. The Vendor Specific area is further defined below in Vendor Specific Digital Diagnostic Monitor TX_FAULT Alarm/Warning Interrupt
on page 37.
JDSU Product Specification 21111542-001
Page 36 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Vendor Specific Digital Diagnostic Monitor TX_FAULT Alarm/Warning Interrupt
The transceiver has the ability to be programmed to indicate TX_FAULT when one of the five DDM signals
goes outside an alarm or warning threshold. This allows the customer the option of using the TX_FAULT as
an interrupt instead of constantly polling the diagnostic signals. The TX_FAULT Alarm/Warning interrupt control bytes are accessible as one of the selectable tables in the Vendor specific area at offset 248-255.
To enable the TX_FAULT as an Alarm/Warning, use the following procedure:
This alarm/warning interrupt enable/latch space will be volatile across power-cycles and resets. This space
can be accessed sequentially and contiguously within the offsets defined for it. If during the course of a
sequential, multi-byte write, the offset being written reaches the end of this vendor specific area, the next byte
of data that will be attempted to be written will be at offset 0.
The Alarm/Warning Interrupt Enable bits are written by the host. They are used by the transceiver to generate
a TX_FAULT signal usable as an interrupt to the host for an alarm/warning condition. The general definition
of the function is that when the host sets an Interrupt Enable bit (offsets 248-251) for an Alarm/Warning to
0b1, then the corresponding Alarm/Warning Latch bit (offsets 252-255) will be latched to 0b1 when the corresponding Alarm/Warning bit (Alarm bits at offsets 112-113 and Warning bits at offsets 116-117) becomes
active. The Alarm/Warning Latch bit will remain 0b1 until the host clears the Latch bit by writing a 0b1 to it, at
which time the transceiver will re-process the Latch bit. While any of the Alarm/Warning Latch bits are a 0b1,
the transceiver will set the TX_FAULT signal active.
Note: When used in the Alarm/Warning Interrupt mode, the TX_FAULT signal does not necessarily indicate
that the transceiver is not transmitting. When TX_FAULT becomes active, the host should disable all
Alarm/Warning Interrupt Enable bits and clear all Alarm/Warning Latch bits In order to determine whether
there is a hardware TX_FAULT that does indicate hardware transmission loss.
Monitor Data Table 9 Alarm/Warning Enables and Latches
Byte
Address
Bit
248
7
Temp High Alarm Interrupt Enable 1
Enable bit for the temperature high alarm.
248
6
Temp Low Alarm Interrupt Enable 1
Enable bit for the temperature low alarm.
248
5
Voltage High Alarm Interrupt Enable 1
Enable bit for the voltage high alarm.
248
4
Voltage Low Alarm Interrupt Enable 1
Enable bit for the voltage low alarm.
248
3
TX Bias High Alarm Interrupt Enable 1
Enable bit for the laser current high alarm.
248
2
TX Bias Low Alarm Interrupt Enable 1
Enable bit for the laser current low alarm.
248
1
TX Power High Alarm Interrupt Enable 1
Enable bit for the fiber coupled power high alarm.
248
0
TX Power Low Alarm Interrupt Enable 1
Enable bit for the fiber coupled power low alarm.
249
7
RX Power High Alarm Interrupt Enable 1
Enable bit for the received power high alarm.
249
6
RX Power Low Alarm Interrupt Enable 1
Enable bit for the received power low alarm.
249
5-0
Reserved
Reserved
250
7
Temp High Warning Interrupt Enable 1
Enable bit for the temperature high warning.
Name
Description of Fields
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 37 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Byte
Address
Bit
250
6
Temp Low Warning Interrupt Enable 1
Enable bit for the temperature low warning.
250
5
Voltage High Warning Interrupt Enable 1
Enable bit for the voltage high warning.
250
4
Voltage Low Warning Interrupt Enable 1
Enable bit for the voltage low warning.
250
3
TX Bias High Warning Interrupt Enable 1
Enable bit for the laser current high warning.
250
2
TX Bias Low Warning Interrupt Enable 1
Enable bit for the laser current low warning.
250
1
TX Power High Warning Interrupt Enable 1
Enable bit for the fiber coupled power high warning.
250
0
TX Power Low Warning Interrupt Enable 1
Enable bit for the fiber coupled power low warning.
251
7
RX Power High Warning Interrupt Enable 1
Enable bit for the received power high warning.
251
6
RX Power Low Warning Interrupt Enable 1
Enable bit for the received power low warning.
251
5-0
Reserved
Reserved
252
7
Temp High Alarm Latch 2
Latched bit for the temperature high alarm.
252
6
Temp Low Alarm Latch 2
Latched bit for the temperature low alarm.
252
5
Voltage High Alarm Latch 2
Latched bit for the voltage high alarm.
252
4
Voltage Low Alarm Latch 2
Latched bit for the voltage low alarm.
252
3
TX Bias High Alarm Latch 2
Latched bit for the laser current high alarm.
252
2
TX Bias Low Alarm Latch 2
Latched bit for the laser current low alarm.
252
1
TX Power High Alarm Latch 2
Latched bit for the fiber coupled power high alarm.
252
0
TX Power Low Alarm Latch 2
Latched bit for the fiber coupled power low alarm.
253
7
RX Power High Alarm Latch 2
Latched bit for the received power high alarm.
253
6
RX Power Low Alarm Latch 2
Latched bit for the received power low alarm.
253
5-0
Reserved
Reserved
254
7
Temp High Warning Latch 2
Latched bit for the temperature high warning.
254
6
Temp Low Warning Latch 2
Latched bit for the temperature low warning.
254
5
Voltage High Warning Latch 2
Latched bit for the voltage high warning.
254
4
Voltage Low Warning Latch 2
Latched bit for the voltage low warning.
254
3
TX Bias High Warning Latch 2
Latched bit for the laser current high warning.
254
2
TX Bias Low Warning Latch 2
Latched bit for the laser current low warning.
254
1
TX Power High Warning Latch 2
Latched bit for the fiber coupled power high warning.
254
0
TX Power Low Warning Latch 2
Latched bit for the fiber coupled power low warning.
255
7
RX Power High Warning Latch 2
Latched bit for the received power high warning.
255
6
RX Power Low Warning Latch 2
Latched bit for the received power low warning.
255
5-0
Reserved
Reserved
Name
Description of Fields
JDSU Product Specification 21111542-001
Page 38 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Byte
Address
Bit
Name
Description of Fields
1. The alarm/warning interrupt enable bits are writable by the host to either 0b0 or 0b1. Their default value after a reset is 0b0. To
enable multiple bits, the host must write the byte at the appropriate offset with a value that is an OR of all bits that are to be set to
the interrupt enabled state.
2. The alarm/warning latch bits are only set to 0b1 by the transceiver, but can be cleared to 0b0 by the host writing a 0b1 to the appropriate bit position. Only those bits that are written to 0b1 will be cleared. Upon clearing a bit, the transceiver will re-process the
Latch bit, and if the corresponding alarm/warning bit is still active, and the corresponding interrupt enable bit is still set to 0b1, the
Latch bit will remain set to 0b1, thus causing TX_FAULT to remain active.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 39 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Mechanical Description
Package Diagram
13.4 ±0.1
Units are in millimeters.
(4X)2 MAX
6.25
13.7 ±0.1
45 ±0.2
2.45 MIN
41.8 ±0.15
9.2 ±0.1
2.6 MAX
55 ±0.25
JDSU Product Specification 21111542-001
Page 40 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Host Card Footprint (Page 1 of 2)
Units are in millimeters.
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 41 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Host Card Footprint (Page 2 of 2)
Units are in millimeters.
JDSU Product Specification 21111542-001
Page 42 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
Suggested Transceiver/Host Interface
1uH
+3.3 volt
1uH
+
10uF
0.1uF
0.1uF
Protocol Vcc
SFP
4.7k to 10kohm
VccT
16
Protocal VCC
10kohm
Tx_Disable 3
TX+
+TD 18
TX-
-TD 19
0.01uF
100 ohm
0.01uF
Laser Driver
Tx_Fault 2
VeeT 20
ASIC
SERDES
VccR
+
10uF
15
0.1uF
0.01uF
+RX 13
RX+
100 ohm
-RX
RX-
Receiver
Amplifier
0.01uF
12
4.7k to 10kohm
Rx_LOS 8
Rate Select 7
VeeR 11
Serial ID
4.7k to 10kohm
+3.3 volt
6
5
4
MOD_DEF(0)
PLD/PAL
MOD_DEF(1)
MOD_DEF(2)
JDSU Product Specification 21111542-001
OCTOBER 2008
Page 43 of 45
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
References
Standards
1. American National Standards Institute Inc. (ANSI), T11/Project 1235-DT/Rev 13, Fibre Channel-Physical
Interface (FC-PI-2 rev. 7). Drafts of this standard are available to members of the standards working committee. For further information see the T11.2 website at www.t11.org.
2. American National Standards Institute Inc. (ANSI), T11.2/Project 1230/Rev10, Fibre Channel-Methodologies for Jitter Specifications (MJS). Drafts of this standard are available to members of the standards
working committee. For further information see the T11.2 website at www.t11.org.
Industry Specifications
3. A.X. Widmer and P.A. Franaszek, “A DC-Balanced, Partitioned-Block, 8B/10B Transmission Code,” IBM
Journal of Research and Development, vol. 27, no. 5, pp. 440-451, September 1983. This paper fully
defines the 8B/10B code. It is primarily theoretical.
4. A.X. Widmer, The ANSI Fibre Channel Transmission Code, IBM Research Report, RC 18855 (82405),
April, 23 1993. Copies may be requested from:
Publications
IBM Thomas J. Watson Research Center
Post Office Box 218
Yorktown Heights, New York 10598
Phone: (914) 945-1259
Fax: (914) 945-4144
5. SFF Document Number: SFF-8472, revision 9.4 “Digital Diagnostic Monitoring Interface for Optical
Transceivers,” August 1, 2002. This document defines features of the 512 bytes of RAM space accessible by the two-wire interface.
6. SFF Document Number: SFF-8079+, Revision 1.1, “SFP Form Factor (Small Form Factor Pluggable)
Rate Select Functionality and Multiple Application Selection Capability”, November 19,2003.
Production Notes
7. The fiber type used for the calibration of Tx and Rx power monitoring functions is a singlemode fiber.
JDSU Product Specification 21111542-001
Page 44 of 45
OCTOBER 2008
JSH-42L3AD3-5, JSH-42L3AD3-5G
JSH-42L3AD3-20
LW 4x/2x/1x FC SFP with DDM
All statements, technical information and recommendations related to the products herein are based upon
information believed to be reliable or accurate. However, the accuracy or completeness thereof is not guaranteed, and no responsibility is assumed for any inaccuracies. The user assumes all risks and liability whatsoever in connection with the use of a product or its application. JDSU reserves the right to change at any time
without notice the design, specifications, function, fit or form of its products described herein, including withdrawal at any time of a product offered for sale herein. JDSU makes no representations that the products
herein are free from any intellectual property claims of others. Please contact JDSU for more information.
JDSU and the JDSU logo are trademarks of JDS Uniphase Corporation. Other trademarks are the property of
their respective holders. Copyright JDS Uniphase Corporation. All rights reserved.
The SFP module described herein contains microcode which is Copyright 2008, JDS Uniphase Corporation.
The purchaser is granted a limited license to use the microcode for the purposes described in this specification. The microcode remains the property of JDSU and may not be decoded, reverse compiled, altered,
extracted from the module storage device, copied, redistributed, or reused without the express written consent of JDSU.
JDSU Product Specification 21111542-001
OCTOBER 2008
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