Hitachi HTR6516R Sfp transceiver for gigabit ethernet fibre channel Datasheet

PRODUCT DATA SHEET
SFP TRANSCEIVER
for Gigabit Ethernet/Fibre Channel
HTR6516 Series
http://www.hitachi-cable.co.jp/
Ref. No.:TE03-02-58-9022B
Mar. ‘03
Page 1 of 15
Features
l Gigabit Ethernet(1.25Gbit/s,10km) and Fibre Channel(1.0625Gbit/s,10km) compliant.
l Fully comply with industry standard Small Form Factor Pluggable transceiver (Hot pluggable).
l Diagnostic monitor as enhanced functions for SFP.
l AEL class 1 laser product per FDA/CDRH and EN60825-1 laser safety regulations.
l LC duplex receptacle.
l Metal cover and inner shield for low EMI emission.
l SFP MSA compliant delatch mechanism and improved handling type (single or double bail type)
delatch mechanism are available.
l +3.3V single power supply.
l Low power consumption (0. 4W(typ.)).
1. General
This document specifies the characteristics of the Small Form Factor Pluggable optical
transceiver (Type:HTR6516) with LC duplex receptacle for 1.25Gbit/s Gigabit Ethernet and
1.0625Gbit/s Fibre Channel. Maximum transmission distance is 10km at the data rate of
1.25Gbit/s and 1.0625Gbit/s. This transceiver apply single mode optical fiber - 9/125.
2. Function
This transceiver is powered from a single +3.3V power supply and operated at a data rate of
1.25Gbit/s or 1.0625Gbit/s(NRZ).
Optical output power is held constant by automatic power
control over the specified operating temperature and voltage ranges.
The optical output is disabled by a TTL logic level input for that purpose. Tx Fault is provided
to indicate the degradation of the laser diode. Loss Of Signal (LOS) output is provided to indicate
the loss of an incoming optical signal. Tx Fault and LOS are open collector type outputs. The type
of this transceiver is identified by Module Definition function using a built-in EEPROM with I2C
interface.
As enhanced functions for SFP, internally measured transceiver temperature, internally
measured supply voltage, laser bias current, laser optical output power and received optical power
can be monitored by reading a built-in memory with I2C interface for that purpose. The interface
pins for the monitor function are common with the Module Definition function.
Dimensions and pin assignment fully comply with MSA (Multi Source Agreement) for SFP
(Small Form Factor Pluggable) optical transceiver.
3. Explanation of Part Number
HTR6516
Model Number
Delatch mechanism
Blank
SFP MSA compliant type
R
Single bail (lever) type
R2
Double bail (lever) type
Page 2 of 15
4. Absolute Maximum Ratings
Stresses in excess of the ratings listed in Table 1 can cause permanent damage to the device
and affect device reliability.
Functional operation of the device is not implied at any condition
in excess of those given in the operating specification.
Table 1. Absolute Maximum Ratings
Parameter
Symbol
Min.
Max.
Unit
Supply Voltage
VCC
0
4.0
V
Data Input Voltage
VIN
VEE
VCC+0.3
V
Receiver Optical Input Power
Pin
-
+3
dBm
Operating Ambient Temperature
TA
-5
70
deg -C
Tstg
-40
85
deg -C
HA
5
85
%
Storage Case Temperature
Operating Relative Humidity (non-condensing)
5. Optical and Electrical Characteristics of Transmitter Portion
Optical and electrical characteristics of transmitter portion are shown in Table 2.
Unless
otherwise stated, minimum and maximum values are specified over the operating ambient
temperature, and humidity ranges, DC power supply voltage range, from beginning to end of life,
using 27-1 pseudo random bit stream with a 50% duty factor.
The logic sense for the DATA input is such that a logic “1”(High) corresponds to the maximum
level of an amplitude modulated light source (Light on), while a logic “0”(Low) corresponds to a
minimum level of an amplitude modulated light source (Light off).
Table 2. Transmitter Optical and Electrical Characteristics
Parameter
Optical Output Power
Center Wavelength
Spectral Width(RMS)
Symbol
Min
Typ
Max
Unit
Po
-9
-
-3
dBm
λ
1290
-
1340
nm
∆λ
-
-
2.8
nm
Eye Mask
-
IEEE 802.3z
Extinction Ratio
-
9.0
-
-
dB
DC Power Supply Voltage
Vcc
3.135
3.3
3.465
V
DC Power Supply Current
Icc
-
-
100
mA
Diff’l Input Swing
VID SWING
500
-
2400
mVp-p
Diff’l Input Impedance
ZID
85
100
115
Ω
Tx Disable Voltage
VD
Vcc-1.3
-
Vcc
V
Tx Enable Voltage
VEN
VEE
-
VEE +0.8
V
Data Input Voltagea
-
-
a. AC coupled inside the module
Page 3 of 15
6. Optical and Electrical Characteristics of Receiver Portion
Optical and electrical characteristics of receiver portion are shown in Table 3.
Unless
otherwise stated, minimum and maximum values are specified over the operating ambient
temperature, and humidity ranges, DC power supply voltage range and wavelength range, from
beginning to end of life, using a 27-1 pseudo random bit stream with a 50% duty factor.
Table 3. Receiver Optical and Electrical Characteristics
Parameter
Symbol
Min
Typ
Max
Unit
Optical input Power (Average) a
PIN
-20b
-
-3b
dBm
Decreasing Light Input
LOST D
-45
-
-23.5
dBm
Increasing Light Input
LOST I
LOSTD+0.5
-
-23
dBm
Hysteresis
LOST H
0.5
-
4.0
dB
DC Power Supply Voltage
Vcc
3.135
-
3.465
V
DC Power Supply Current
Icc
-
-
100
mA
VOD SWING
1100
1600
2000
mVp-p
to
-
-
0.28
ns
Low
VOL
-
-
Vee+0.4
V
High
VOH
Vcc-0.9
-
-
V
Decreasing Light Input
LOSRT D
-
-
100
µs
Increasing Light Input
LOSRT I
-
-
100
µs
LOS Threshold:
Data Output Voltagec
Diff’l Output Swing
Output Transition Time
LOS Output Voltage:
d
e
LOS Response Time:
1x10-12
a.
At a BER of
and an extinction ratio of 9.0dB.
b.
At 1.25Gbit/s and 1.0625Gbit/s.
c.
AC coupled inside the module.
d. Between 20% and 80% (50% duty cycle).
e. TTL compatible.
Page 4 of 15
7. Physical Design
The package outline of SFP MSA compliant delatch mechanism is shown in Figure 1
.
0.413
max
10.5
0.413
10.5
1.811
max
46.0
0.339
8.6
Side View
Top View
Color of LC receptacle ; Blue
1.772
45.0
10
0.539
13.7
(11)
0.362 0.531
9.2 13.5
Bottom View
(20)
1
0.453
11.5
opposite(top) side
1.362
34.6
1.646
41.8
Unless otherwise stated, typical values are shown
unit:
Figure 1. The package outline of SFP MSA compliant delatch mechanism
inch
mm
Page 5 of 15
The package outline of bail (lever) delach mechanism type is shown in Figure 2.
0.347
8.8
Side View
0.079
2.0
0.433
max
11.00
1.791
max
45.5
0.339
8.6
0.339
8.6
Side View
0.079
max
2.0
Top View
Color of LC receptacle; Blue
1.772
45.0
10
0.539
13.7
(11)
0.362 0.531
9.2 13.5
Bottom View
1
0.453
11.5
(20)
opposite(top) side
1.362
34.6
1.646
41.8
unit:
Unless otherwise stated, typical values are shown
Figure 2. The package outline of Single bail (lever) delach mechanism type
inch
mm
Page 6 of 15
The package outline of double bail delach mechanism type is shown in Figure 3.
0.787
20.0
Side View
0.079
2.0
0.433
max
11.00
1.791
max
45.5
0.339
8.6
0.339
8.6
Side View
0.079
max
2.0
Top View
Color of LC receptacle; Blue
1.772
45.0
10
0.539
13.7
(11)
0.362 0.531
9.2 13.5
Bottom View
1
0.453
11.5
(20)
opposite(top) side
1.362
34.6
1.646
41.8
Unless otherwise stated, typical values are shown
Figure 3. The package outline of double bail delach mechanism type
unit:
inch
mm
Page 7 of 15
8. Label
Label that describe the following items is indicated on the top of transceiver.
Product name, Serial number, Wavelength, Manufacture name and “CLASS 1 LASER
PRODUCT”.
9. PINOUT
Pinout is shown in Table 4.
Table 4. Pin Designations
Name
Symbol
Pin
Pin
Symbol
Name
Transmitter Ground
VeeT
20
1
VeeT
Transmitter Ground
Inv. Transmit
Data In
TD-
19
2
Tx Fault
Transmitter Fault
Indication
Transmit Data In
TD+
18
3
Tx Disable
Transmitter Disable
Transmitter Ground
VeeT
17
4
MOD_DEF(2)*
Module Definition 2
Transmitter Power
VccT
16
5
MOD_DEF(1)*
Module Definition 1
Receiver Power
VccR
15
6
MOD_DEF(0)*
Module Definition 0
Receiver Ground
VeeR
14
7
(Rate Select)
Unused function
Received Data Out
RD+
13
8
LOS
Loss of Signal
Inv. Received
Data Out
RD-
12
9
VeeR
Receiver Ground
Received Ground
VeeR
11
10
VeeR
Receiver Ground
* Mod-Def 0,1,2 are the module definition pins. They should be pulled up with a 4.7K-10KΩ
resistor on the host board.
Mod-Def 0 is grounded by the module to indicate that the module is present.
Mod-Def 1 is the clock line of two wire serial interface (I2C) for serial ID.
Mod-Def 2 is the data line of two wire serial interface (I2C) for serial ID.
For use of two wire serial interface (I2C), referring to Philips I2C bus specification or ATMEL
AT24C01A/02/04 data sheet is recommended. Refer to URL below for more detail:
http://www.semiconductors.philips.com/buses/i2c/facts/index.html or,
http://www.atmel.com/acrobat/doc0180.pdf
Page 8 of 15
10. Block Diagram and Recommended Circuit
Block diagram and recommended decoupling and termination for HTR6516 is illustrated in
Figure 4.
This recommendation will provide a good performance of the optical transceiver.
Host board layout, the design of SFP cage and SFP electrical connector should comply with the
SFP MSA requirements.
Protocol Vcc
Vcc
10 uF
SFP Module
0.1 uF
1 uH
0.1 uF
30k ohm
1 uH
4.7k to 10k ohm
10 uF
LOS
Rate Select
(Unused)
LOS
*
RD-
*
RD+
100 ohm
0.33 uF
Preamp/
Postamp
0.33 uF
VeeR
Protocol IC
4.7k to 10k ohm
180 ohm
180 ohm
SerDes IC
10k ohm
VccT
10 uF 0.1 uF
Tx Disable
Tx Disable
Tx Fault
*
TD-
*
TD+
0.33 uF
Laser Driver
100 ohm
0.33 uF
Tx Fault
VeeT
Vcc
Serial ID
EEPROM
Diagnostic
Monitoring
Function
MOD_DEF(0)
MOD_DEF(1)
MOD_DEF(2)
PLD / PAL
4.7k to 10k ohm
4.7k to 10k ohm
4.7k to 10k ohm
* Thick line: 50 ohm microstrip line
Figure 4. Block Diagram and Recommended Circuit
Page 9 of 15
1 1 .Serial identification
This transceiver features an EEPROM for Serial ID. Contents of the Serial ID are shown in
Table 5.
Table 5. EEPROM Serial ID Memory Contents
Data
Address
Field
Size
(Bytes)
Name of Field
0
1
2
3-10
11
12
13
14
15
16
17
18
19
20-35
1
1
1
8
1
1
1
1
1
1
1
1
1
16
Identifier
Ext.Identifier
Connector
Transceiver
Encoding
BR, Nominal
Reserved
Length(9u)-km
Length(9u)
Length(50u)
Length(62.5u)
Length(Copper)
Reserved
Vendor name
36
37-39
40-55
1
3
16
Reserved
Vendor OUI
Vendor PN
56-59
60-61
62
63
4
2
1
1
Vendor rev
Wavelength
Reserved
CC_BASE
64-65
2
Options
66
67
68-83
1
1
16
BR, max
BR, min
Vendor SN
84-91
8
Date code
92
1
Diagnostic
Monitoring Type
58 (01011000 in binary)
93
1
Enhanced optins
80 (10000000 in binary)
94
1
95
1
SFF-8472
Compliance
CC_EXT
96-127
128-511
511-n
32
384
-
Read-only
Reserved
Value(Hex)
BASE ID FIELDS
03
04
07
00 00 00 02 12 00 01 01
03
00
00
0A
64
00
00
00
00
48 69 74 61 63 68 69 20
43 61 62 6C 65 20 20 20
00
00 40 66
48 54 52 36 35 31 36 20
20 20 20 20 20 20 20 20
48 54 52 36 35 31 36 52
20 20 20 20 20 20 20 20
48 54 52 36 35 31 36 52
32 20 20 20 20 20 20 20
20 20 20 20
05 1E
00
Check sum(Variable)
EXTENDED ID FIELDS
00 1A
05
05
30 30 30 31 32 33 20 20
20 20 20 20 20 20 20 20 (*1)
30 32 31 31 31 38 30 30 (*2)
01
Remark
SFP
LC connector
Transceiver codes
NRZ
Bit rate is not specified
10km(units of km)
10000m(units of 100m)
N ot supported
N ot supported
N ot supported
N ot supported
"Hitachi Cable"(ASCII)
"HTR6516"(ASCII)
PN of SFP MSA compliant delatch type
"HTR6516R"(ASCII)
PN of single bail delatch type
"HTR6516R2"(ASCII)
PN of double bail delatch type
(ASCII)
1310nm(16-bit unsigned integer)
Check code for Base ID Fields
Loss of Signal, TX_FAULT,
TX_DISABLE implemented
5%(units of %)
5%(units of %)
Serial number of transceiver(ASCII)
(*1 Sample of number is "000123")
Manufacturing date code(ASCII)
(*2 Sample of date is "02111800")
Digital
Diagnostic
monitoring
implemented.
Calibration type is
“External Calibration”.
Rx power
measurement type is “Average Power ”.
Alarm/Warning flags implemented for
all monitored quantities.
Includes functionality described in
Rev.9.0 SFF-8472.
Check code for Extended ID Fields
Check sum(Variable)
VENDOR SPECIFIC ID FIELDS
Unused
Filled by zero
Unused
Filled by zero
Unused
Filled by zero
Page 10 of 15
12.Enhanced Functions
Enhanced functions interface uses the 2 wire address 1010001X (0xA2). Memory contents of
enhanced functions are shown in Table 6.1.
Table 6.1 Memory Contents / 2 wire address 1010001X (0xA2)
Data
Address
Field
Size
(Bytes)
00-01
02-03
04-05
06-07
08-09
10-11
12-13
14-15
16-17
18-19
20-21
22-23
24-25
26-27
28-29
30-31
32-33
34-35
36-37
38-39
40-55
56-59
60-63
64-67
68-71
72-75
76-77
78-79
80-81
82-83
84-85
86-87
88-89
90-91
92-94
95
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
2
16
4
4
4
4
4
2
2
2
2
2
2
2
2
3
1
96-97
98-99
100-101
102-103
104-105
106-109
110
111
112-119
2
2
2
2
2
4
1
1
8
120-127
128-255
4
136
Name
Remark
CONSTANTS FIELDS
Temperature High Alarm
Set to 85 deg-C
Temperature Low Alarm
Set to -15 deg-C
Temperature High Warning
Set to 80 deg-C
Temperature Low Warning
Set to -5 deg-C
Vcc High Alarm
Set to 3.6 V
Vcc Low Alarm
Set to 3.0 V
Vcc High Warning
Set to 3.5 V
Vcc Low Warning
Set to 3.1 V
Laser Bias High Alarm
Various at each device
Laser Bias Low Alarm
Various at each device
Laser Bias High Warning
Various at each device
Laser Bias Low Warning
Various at each device
Tx Power High Alarm
Manufacture measurement plus 3 dB
Tx Power Low Alarm
Manufacture measurement minus 3dB
Tx Power High Warning
Manufacture measurement plus 2 dB
Tx Power Low Warning
Manufacture measurement minus 2dB
Rx Power High Alarm
Maximum input power plus 1 dB
Rx Power Low Alarm
Minimum input power minus 2 dB
Rx Power High Warning
Maximum input power plus 0.5 dB
Rx Power Low Warning
Minimum input power minus 1 dB
Reserved
All bytes set to 0x00
Rx Power Calibration Data R4
Single precision floating-point numbers (various
values at each device for incompatibility with “internal
Rx Power Calibration Data R3
calibration ”)
Rx Power Calibration Data R2
Rx Power Calibration Data R1
Rx Power Calibration Data R0
Laser Bias Calibration Data B1
Unsigned fixed-point number (set to 1) *
Laser Bias Calibration Data B0
16-bit signed 2's complement number (set to 0) *
Tx Power Calibration Data P 1
Unsigned fixed-point number (set to 1) *
Tx Power Calibration Data P 0
16-bit signed 2's complement number (set to 0) *
Temp. Calibration Data T 1
Unsigned fixed-point number (set to 1) *
Temp. Calibration Data T 0
16-bit signed 2's complement number (set to 0) *
Vcc Calibration Data V1
Unsigned fixed-point number (set to 1) *
Vcc Calibration Data V0
16-bit signed 2's complement number (set to 0) *
Reserved
All bytes set to 0x00
Checksum
Low order 8 bits of the sum of byte 0-94.
VARIABLES FIELDS
Measured Temperature
Raw 16-bit A/D value (see Table 6.2)
Measured Vcc
Raw 16-bit A/D value (see Table 6.2)
Measured Laser Bias
Raw 16-bit A/D value (see Table 6.2)
Measured Tx Power
Raw 16-bit A/D value (see Table 6.2)
Measured Rx Power
Raw 16-bit A/D value (see Table 6.2)
Reserved
All bytes set to 0x00
Logic States
See Table 6.4
AD Updated
See Table 6.4
Alarm and Warning Flags
See Table 6.5
VENDOR SPECIFIC FIELDS
Vendor Specific
Do not access in order to operate normally
No physical memory
* Slopes B1=P 1=T 1=V1=1, intercepts B0=P 0=T 0=V0=0, for compatibility with “internal calibration ”.
Page 11 of 15
The measured values located at bytes 96-105 (in the 2 wire address 0xA2) are raw A/D values (16-bit
integers) of transceiver temperature, supply voltage, laser bias current, laser optical output power and
received power. All the measured values are "externally calibrated" over specified temperature and
supply voltage, and then it is necessary to convert raw A/D values to real world units using the
external calibration constants located at bytes 56-91 (0xA2) by the manner as shown in Table 6.2.
Byte
96
97
98
99
100
101
102
103
104
105
Table 6.2 Measured Values / 2 wire address 1010001X (0xA2)
Name
Description
Temp MSB
Internally measured transceiver temperature, TAD (16-bit signed 2's
complement integer). Actual temperature, T, is given by, T=T1*T AD+T0,
Temp LSB
where T1 and T0 are calibration data at bytes 84-87. The result is 16-bit
signed 2's complement value with LSB equal to 1/256 deg -C (see Table
6.3a), yielding a total range of -128 to +128 deg-C. Accuracy of result is
better than +/-3 deg -C.
Vcc MSB
Internally measured supply voltage, VAD (16-bit unsigned integer). Actual
voltage, V, is given by, V=V1*VAD+ V0, where V1 and V0 are calibration
Vcc LSB
data at bytes 88-91. The result is 16-bit unsigned value with LSB equal to
100 µV (see Table 6.3b), yielding a total range of 0 to 6.55 V. Accuracy of
result is better than +/-50 mV. Note that transmitter supply voltage
measured since VccT and VccR are isolated.
Laser Bias MSB
Measured Laser bias current, BAD (16-bit unsigned integer). Actual
current, B, is given by, B=B1*BAD+B0, where B1 and B0 are calibration
Laser Bias LSB
data at bytes 76-79. The result is 16-bit unsigned value with LSB equal to
2 µA (see Table 6.3b), yielding a total range of 0 to 131 mA. Accuracy of
result is better than +/-8 mA.
Tx Power MSB
Measured Tx power, PAD (16-bit unsigned integer). Actual power, P, is
given by, P=P1*P AD+P0, where P1 and P0 are calibration data at bytes
Tx Power LSB
82-85. The result is 16-bit unsigned value with LSB equal to 0.1 µW (see
Table 6.3b), yielding a total range of 0 to 6.55 mW. Accuracy is better
than +/-3dBm.
Rx Power MSB
Measured Rx power, RAD (16-bit unsigned integer). Actual power, R, is
given by
Rx Power LSB
R = R4*RAD4 + R3*RAD3 + R2*RAD2 + R1*RAD + R0,
where R4, R3, R2, R1 and R0 are calibration data at bytes 56-75. The result
is 16-bit unsigned value with LSB equal to 0.1 µW (see Table 6.3b),
yielding a total range of 0 to 6.55 mW. Accuracy is better than +/-3dBm
over the specified optical input power.
The formats of values shown in Table 6.2 are interpreted below. The result of temperature, T, and
the calibration intercepts, T0, V0, B0, and P0, are 16-bit signed 2's complement numbers with
corresponding LSB (e.g. laser bias, B0, has 2 µA LSB) as shown in Table 6.3a. The result of Vcc, V,
laser bias, B, Tx power, P, and Rx power, R are 16-bit unsigned numbers with corresponding LSB (e.g.
laser bias, B, has 2 µA LSB) as shown in Table 6.3b. The calibration slopes, T1, V1, B1, and P1, are
unsigned fixed-point numbers as shown in Table 6.3c. The calibration coefficients, R4, R3, R2, R1, and
R0, are IEEE-754 single precision floating-point numbers as shown in Table 6.3d.
Page 12 of 15
Table 6.3a 16-Bit Signed 2's Complement Number (MSB at low address)
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
Bit 1
Bit 0
MSB SIGN
214
213
212
211
210
29
28
LSB
27
26
25
24
23
22
21
20
Table 6.3b 16-bit Unsigned Number (MSB at low address)
MSB
LSB
Bit 7
215
27
Bit 6
214
26
Bit 5
213
25
Bit 4
212
24
Bit 3
211
23
Bit 2
210
22
Bit 1
29
21
Bit 0
28
20
Table 6.3c Unsigned Fixed-Point Number (MSB at low address)
MSB
LSB
Bit 7
27
2-1
Bit 6
26
2-2
Bit 5
25
2-3
Bit 4
24
2-4
Bit 3
23
2-5
Bit 2
22
2-6
Bit 1
21
2-7
Bit 0
20
2-8
Table 6.3d IEEE-754 Single Precision Floating-Point Number (MSB at low address)
MSB
LSB
Bit 7
SIGN
EXPONENT
Bit 6
Bit 5
Bit 4
Bit 3
Bit 2
EXPONENT
MANTISSA
MANTISSA
MANTISSA
Bit 1
Bit 0
This transceiver is implemented two optional status bits, "Logic States" at byte 110 (0xA2) and "A/D
Updated" at byte 111 (0xA2) as shown in Table 6.4. "A/D updated" status bits allows the user to
verify if an update from the analog -digital conversion has occurred to the measured values,
temperature, Vcc, laser bias, Tx power and Rx power. The user writes the byte to 0x00. Once a
conversion is complete for a given value, its bit will change to '1'.
Byte
110
110
110
110
110
110
110
110
111
111
111
111
111
111
111
111
Bit
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
Table 6.4 Optional Status Bits / 2 wire address 1010001X (0xA2)
Name
Description
Tx Disable State
Optional digital state of the Tx Disable input pin.
Soft Tx Disable Control
Not supported (set to 0).
Reserved
Set to 0.
Rx Rate Select State
Not supported (set to 1).
Soft Rate Select Control
Not supported (set to 0).
Tx Fault
Optional digital state of the Tx Fault output pin.
LOS
Optional digital state of the LOS output pin.
Power on Logic
Bit will be 0 when the analog monitoring is active.
Temp A/D Valid
Indicates A/D value in Bytes 96/97 is valid.
Vcc A/D Valid
Indicates A/D value in Bytes 98/99 is valid.
Laser Bias A/D Valid
Indicates A/D value in Bytes 100/101 is valid.
Tx Power A/D Valid
Indicates A/D value in Bytes 102/103 is valid.
Rx Power A/D Valid
Indicates A/D value in Bytes 104/105 is valid.
Reserved
Set to 0.
Reserved
Set to 0.
Reserved
Set to 0.
Page 13 of 15
Each of the measured values has a corresponding high alarm, low alarm, high warning and low
warning threshold level at location 00-39 (0xA2) written as the data format of a corresponding value
shown in Table 6.2. Alarm and warning flags at bytes 112-119 (0xA2) are defined as follows,
(1) Alarm flags indicate conditions likely to result (or have resulted) in link failure and cause for
immediate action,
(2) Warning flags indicate conditions outside the guaranteed operating specification of transceiver but
not necessarily causes of immediate link failures.
Table 6.5 Alarm and Warning Flags / 2 wire address 1010001X (0xA2)
Byte
112
112
112
112
112
112
112
112
113
113
113
114
115
116
116
116
116
116
116
116
116
117
117
117
117
117
Bit(s)
7
6
5
4
3
2
1
0
7
6
5-0
7-0
7-0
7
6
5
4
3
2
1
0
7
6
5-0
7-0
7-0
Name
Temp. High Alarm
Temp. Low Alarm
Vcc High Alarm
Vcc Low Alarm
Laser Bias High Alarm
Laser Bias Low Alarm
Tx Power High Alarm
Tx Power Low Alarm
Rx Power High Alarm
Rx Power Low Alarm
Reserved
Reserved
Reserved
Temp. High Warning
Temp. Low Warning
Vcc High Warning
Vcc Low Warning
Laser Bias High Warning
Laser Bias Low Warning
Tx Power High Warning
Tx Power Low Warning
Rx Power High Warning
Rx Power Low Warning
Reserved
Reserved
Reserved
Description
Set when temp. monitor value exceeds high alarm level.
Set when temp. monitor value is below low alarm level.
Set when Vcc monitor value exceeds high alarm level.
Set when Vcc monitor value is below low alarm level.
Set when laser bias monitor value exceeds high alarm level.
Set when laser bias monitor value is below low alarm level.
Set when Tx power monitor value exceeds high alarm level.
Set when Tx power monitor value is below low alarm level.
Set when Rx power monitor value exceeds high alarm level.
Set when Rx power monitor value is below low alarm level.
All bits set to 0.
All bits set to 0.
All bits set to 0.
Set when temp. monitor value exceeds high warning level.
Set when temp. monitor value is below low warning level.
Set when Vcc monitor value exceeds high warning level.
Set when Vcc monitor value is below low warning level.
Set when laser bias monitor value exceeds high warning level.
Set when laser bias monitor value is below low warning level.
Set when Tx power monitor value exceeds high warning level.
Set when Tx power monitor value is below low warning level.
Set when Rx power monitor value exceeds high warning level.
Set when Rx power monitor value is below low warning level.
All bits set to 0.
All bits set to 0.
All bits set to 0.
Page 14 of 15
13. Inspection
Inspection items are as follows:
(1) Appearance
(2) Dimensions
(3) Optical output power
(4) Optical waveform
(5) Optical input power
a) Average sensitivity
b) Loss of Signal / Decreasing light input
c) Loss of Signal / Increasing light input
(6) Power supply current
14. Packing
The optical transceiver shall be packed in sturdy carton box(es) when shipping.
15. Caution
(1) Do not stare into optical output port although this product is designed to meet the class 1
laser regulation.
(2) The housing of the transceiver is possible to crack or dissolve against the particular
chemicals.
Although we recommend to use the aqueous fluid in the cleaning, the below
chemicals are checked not to affect to the housing.
cleaning process.
Pay attention in the solder flux and
We recommend checking the appropriateness of the cleaning fluid in
advance.
/ methyl alcohol, ethyl alcohol, butyl alcohol, isopropyl alcohol, hexane, cyclohexane,
naphtha, tetrachloroethylene, propylene glycol
< Do not use : Chemicals which are checked to crack or dissolve>
/ trichloroethylene, trichloroethane, benzen, methyl ethyl ketone, chloroform, toluene,
acetone, phenol, ethyl acetate,
methylene di chloride
(3) Optical connectors should be cleaned completely by proper cleaning process before insertion to
optical receptacles of the transceiver to avoid contamination inside the optical receptacle.
The contamination may cause serious degradation of transmission performance.
Using
forced nitrogen and some kind of cleaning stick ("CLETOP, stick type" for LC/MU connector
supplied by NTT international is recommended) should be used if the receptacle get
contaminated by miss-treating optical connectors.
= MEMO =
= Notice =
- All information contained in this document is subject to change without notice.
- No responsibility is assumed by Hitachi Cable, Ltd. For its use nor for any infringements
of third parties, which may result from its use.
- Products described in this document are not intended for use in implantation or other life
support applications where malfunction may result in injury or death to persons.
- Customer must contact Hitachi Cable, Ltd. to obtain the latest specification to verify,
before placing any order, that the information contained herein is current.
http://www.hitachi-cable.co.jp/
Hitachi Cable America, Inc.
http://www.hitachi-cable.com/
Ref. No.:TE03-02-58-9022B
Mar. ‘03