OPLINK DTR1250SMGBL1

OCP
DTR-1250-SM-GB-L1
GBIC Single Mode Transceiver
Features
; Compliant with GBIC Specification, Rev. 5.5
; Compliant with IEEE 802.3z 1000BASE-LX
Specifications for Gigabit Ethernet
; Compliant with Optical Interface Requirements in
Annex F of GBIC Specification, Rev. 5.5
; Compliant with GBIC Serial Module Definition
Protocol (Module Definition 4 in Annex D)
; 10km with Single Mode Fiber
; Hot-pluggable
; Excellent EMI & ESD Protection
; Eye Safe (Class I Laser Safety)
; Duplex SC Optical Interface
; Single +5V Power Supply
Description
The DTR-1250-SM-GB-L1 GBIC transceiver provides a
long haul, single mode solution for 1000BASE-LX Gigabit
Ethernet ports in a networking switch. The transceiver
uses a 1310nm Fabry Perot laser and a high sensitivity
receiver to provide a minimum optical link power budget
of 11dB, corresponding to a minimum distance of 10km,
assuming fiber loss of 0.45dB/km. It satisfies Class I
Laser Safety requirements in accordance with the US
FDA/CDRH and international IEC-825 standards.
The DTR-1250-SM-GB-L1 transceiver is fully compliant
with Annex F of GBIC specification, Rev. 5.5.
The transceiver connects to a standard 20-pad GBIC
connector for hot plug capability. This allows the system
designer to make configuration changes or maintenance
by simply plugging in different types of converters without
removing the power supply from the host system.
The transceiver operates from a single +5V power supply
over an operating case temperature range of -5°C to +70°C.
Absolute Maximum Ratings
Parameter
Symbol
Minimum
Maximum
Units
Storage Temperature
Tst
- 40
+ 85
°C
Operating Case Temperature
Top
-5
+ 70
°C
Supply Voltage
VDD
0
+ 6.0
V
Input Voltage
Vin
0
+ 6.0
V
Optical Communication Products, Inc.
1
21737-0381, Rev. C
09-24-2003
DTR-1250-SM-GB-L1
Transmitter Performance Characteristics (over Operating Case Temperature, VCC = 4.75 to 5.25V)
All parameters guaranteed only at typical data rate
Parameter
1
Operating Data Rate
Optical Output Power2
Center Wavelength
Spectral Width (RMS)2
Extinction Ratio
Symbol
B
Po
λc
Minimum
Typical
Maximum
Units
- 9.0
1250
-
- 3.0
Mb/s
dBm
1290
1310
1340
nm
∆λRMS
9
-
2.5
-
nm
dB
Phi /Plo
Transmitter Disabled Optical Output Power 2
Pdis
-
-
- 35.0
dBm
Deterministic Jitter
DJ
-
-
80
ps
Total Jitter
TJ
-
-
227
ps
RIN
-
-
- 120
dB/Hz
Relative Intensity Noise
Transmitter Output Eye
Compliant with Eye Mask Defined in IEEE 802.3z standard
rate ranges from 125Mb/s to 1300Mb/s. However, some degradation may be incurred in overall performance.
Measured average power coupled into single mode fiber (SMF).
1
Data
2
Receiver Performance Characteristics (over Operating Case Temperature, VCC = 4.75 to 5.25V)
All parameters guaranteed only at typical data rate
Minimum
Typical
Maximum
Units
1
Parameter
B
-
1250
-
Mb/s
Minimum Input Optical Power (10-12 BER)2
Pmin
- 20.0
-
-
dBm
Maximum Input Optical Power (10-12 BER)2
Pmax
- 3.0
-
-
dBm
Plos+
Plos-
- 30.0
-
- 20.0
-
dBm
dBm
Operating Data Rate
LOS Thresholds
Increasing Light Input
Decreasing Light Input
Symbol
LOS Hysteresis
-
0.5
-
-
dB
Deterministic Jitter
DJ
-
-
170
ps
Total Jitter
TJ
-
-
266
ps
Wavelength of Operation
λ
1100
-
1600
nm
Optical Return Loss
-
12
-
-
dB
Stressed Receiver Sensitivity
Compliant with IEEE 802.3z standard
1
Data
2
rate ranges from 125Mb/s to 1300Mb/s. However, some degradation may be incurred in overall performance.
Measured with 27-1 PRBS at 1250Mb/s at 1310nm wavelength.
Laser Safety: All transceivers are Class I Laser products per
FDA/CDRH and IEC-825 standards. They must be operated
under specified operating conditions.
Optical Communication Products, Inc.
DATE OF MANUFACTURE:
MANUFACTURED IN THE USA
This product complies with
21 CFR 1040.10 and 1040.11
Meets Class I Laser Safety Requirements
2
21737-0381, Rev. C
09-24-2003
DTR-1250-SM-GB-L1
Transmitter Electrical Interface (over Operating Case Temperature, VCC = 4.75 to 5.25V)
Parameter
1
Symbol
Minimum
Typical
Maximum
Units
V
VPP-DIF
0.65
-
2.0
2
Input HIGH Voltage (TX_DISABLE)
VIH
2.0
-
VDD + 0.3
V
Input LOW Voltage (TX_DISABLE)2
VIL
0
-
0.8
V
Output HIGH Voltage (TX_FAULT)3
VOH
VCC - 0.5
-
VCC + 0.3
V
3
VOL
0
-
0.5
V
Input Voltage Swing (+TX_DAT & -TX_DAT)
Output LOW Voltage (TX_FAULT)
1
Differential peak-to-peak voltage.
2
There is an internal 5.1kΩ pullup resistor to VDDT.
3
Open collector compatible, 4.7 to 10kΩ pullup resistor to VCC (Host Supply Voltage).
Receiver Electrical Interface (over Operating Case Temperature, VCC = 4.75 to 5.25V)
Parameter
Symbol
Minimum
Typical
Maximum
Units
Output Voltage Swing (+RX_DAT & -RX_DAT)1
VPP-DIF
0.60
-
2.0
Vp-p
2
VOH
VCC - 0.5
-
VCC + 0.3
V
2
VOL
0
-
0.5
V
Output HIGH Voltage (RX_LOS)
Output LOW Voltage (RX_LOS)
1
Differential peak-to-peak voltage across external 150Ω load.
2
Open collector compatible, 4.7 to 10kΩ pullup resistor to VCC (Host Supply Voltage).
Electrical Power Supply Characteristics (over Operating Case Temperature, VCC = 4.75 to 5.25V)
Symbol
Minimum
Typical
Maximum
Units
Supply Voltage
Parameter
VDD
4.75
5.0
5.25
V
Supply Current
IDD
-
160
220
mA
Module Definition
Module
Definition
MOD_DEF(0)
pin 4
MOD_DEF(1)
pin 5
MOD_DEF(2)
pin 6
Interpretation by Host
4
TTL LOW
SCL
SDA
Serial module definition protocol
Pin Assignments
PIN
FUNCTION
PIN
FUNCTION
1
RX_LOS (RX LOSS OF SIGNAL)
11
RGND (RX GROUND)
2
RGND (RX GROUND)
12
-RX_DAT (RX DATA OUT -)
3
RGND (RX GROUND)
13
+RX_DAT (RX DATA OUT +)
4
MOD_DEF(0)
14
RGND (RX GROUND)
5
MOD_DEF(1)
15
VDDR (RX SUPPLY VOLTAGE)
6
MOD_DEF(2)
16
VDDT (TX SUPPLY VOLTAGE)
7
TX_DISABLE
17
TGND (TX GROUND)
8
TGND (TX GROUND)
18
+TX_DAT (TX DATA IN +)
9
TGND (TX GROUND)
19
-TX_DAT (TX DATA IN -)
10
TX_FAULT
20
TGND (TX GROUND)
3
21737-0381, Rev. C
09-24-2003
DTR-1250-SM-GB-L1
Example of host board schematic
TTL LOW
(internally connected to GND)
SCL
SDA
1 µH coil or ferrite bead
(<0.2Ω series resistance)
VDD
(5V)
+
10
0.1
5
6
15
+
10
+
4
10
0.1
0.1
10
GBIC
+TX_DAT
18
TX_DISABLE
75Ω line
75Ω line
12
19
4.7kΩ
to 10kΩ
RX_LOS
13
75Ω line
-TX_DAT
TX_FAULT
1
16
75Ω line
VCC (HOST)
+RX_DAT
to 75Ω load
-RX_DAT
to 75Ω load
7
2,3,8,9,11,14,17,20
Application Notes
Connection of the GBIC transceiver to the host system: The
GBIC’s 20-pad connector and two guide tabs connected to the
transceiver’s circuit ground connect the GBIC to the host
system. The two ground tabs make contact to the host circuit
ground before the connector pad and discharge any possible
component-damaging static electricity. Additionally, surge
currents are eliminated by using a special slow start circuit
and two-stage contact sequence where operational signals and
grounds make contact prior to the power supply (as specified
in the GBIC specification, Rev. 5.5).
TX DISABLE: When the TX_DISABLE pin is at logic HIGH,
the transmitter optical output is disabled (less than -35dBm).
Serial Identification: The DTR-1250-SM-GB-L1 transceivers
are compliant with Annex D (Module Definition 4) of the GBIC
specification, Rev. 5.5, which defines the Serial Identification
Protocol.
The module definition of GBIC is indicated by the three module
definition pins, MOD_DEF(0), MOD_DEF(1) and MOD_DEF(2).
Module Definition 4 specifies a serial definition protocol with
a two-wire I2C serial interface; upon power up, MOD_DEF(1:2)
appear as NC (no connection), and MOD_DEF(0) is TTL LOW.
When the host system detects this condition, it activates the
serial protocol and generates the serial clock signal (SCL). The
negative edge clocks data from the GBIC EEPROM.
Electrical interface: All signal interfaces are compliant with
the GBIC specification, Rev. 5.5. The high speed DATA
interface is differential AC-coupled and can be directly
connected to either a 5V or 3.3V SERDES IC. All low speed
control and sense input/output signals are open collector TTL
compatible and should be pulled up with a 4.7 - 10kΩ resistor
on the host board.
The serial data signal (SDA) is for serial data transfer. The host
uses SDA in conjunction with SCL to mark the start and end of
serial protocol activation.
Loss of Signal (LOS): The Loss of Signal circuit monitors the
level of the incoming optical signal and generates a logic HIGH
when an insufficient photocurrent is produced.
The data transfer protocol and the details of the mandatory and
vendor specific data structures are defined in Annex D of the
GBIC specification, Rev. 5.5.
TX FAULT: The output indicates LOW when the transmitter is
operating normally, and HIGH when the transmitter or laser current
is excessive. TX_FAULT is an open collector/drain output and
should be pulled up with a 4.7 - 10kΩ resistor on the host board.
Power supply and grounding: The power supply line should
be well-filtered. All 0.1µF power supply bypass capacitors
should be as close to the GBIC transceiver module as possible.
The module case is AC-grounded internally to circuit ground.
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21737-0381, Rev. C
09-24-2003
DTR-1250-SM-GB-L1
Package Outline
[1.49MAX]
38.0MAX
12
.472
12.7
.500
25.40
1.000
8.9
.35
1MAX
2X .04 MAX CLOSE
8.18
.322
0
- 0.10
+.000
2X .050
- .004
13.54MAX
.533MAX
PIN 10
1.27
0
1.63 - 0.15
+.000
.064 - .006
GUIDE
SLOTS
HEIGHT
PIN 1
58 MAX
2.28 MAX
3.05+0.05
.120+.002
PIN 20
+0.04
10.06
- 0.20
+.002
.396
- .008
27.7
1.09
GUIDE SLOTS WIDTH
0
- 0.13
+.000
1.200
- .005
30.48
Dimensions in inches [mm]
Default tolerances:
.xxx = + .005”, .xx = + .01”
Ordering Informaton
Model Name
Nominal Wavelength
Optical Link Power Budget
Distance1
DTR-1250-SM-GB-L1
1310nm
11dB min.
10km
1
The indicated transmission distance is for guidelines only, not guaranteed. The exact distance is dependent on the fiber loss, connector and
splice loss, and allocated system penalty. Longer distances can be supported if the optical link power budget is satisfied.
Optical Communication Products, Inc.
6101Variel Avenue, Woodland Hills, CA 91367, Tel.: 818-251-7100, FAX: 818-251-7111, www.ocp-inc.com
Optical Communication Products, Inc. reserves the right to make changes in equipment design or specifications without notice. Information supplied by Optical Communication
Products, Inc. is believed to be accurate and reliable. However, no responsibility is assumed by Optical Communication Products, Inc. for its use nor for any infringements
of third parties, which may result from its use. No license is granted by implication or otherwise under any patent right of Optical Communication Products, Inc.
© 2003, Optical Communication Products, Inc.
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21737-0381, Rev. C
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