Semiconductor Group
FEATURES
Compliant with Gigabit Ethernet standard
Meets mezzanine standard height of 9.8 mm
Compact integrated transceiver unit with
VCSEL laser diode transmitter
Integrated receiver
Duplex SC receptacle
Class 1 FDA and IEC laser safety compliant
Single power supply (5 V or 3.3 V)
PECL signal detect indicator
PECL differential inputs and outputs
Process plug included
Wave solderable and washable with process plug
inserted
For distances of up to 550 m (dependent on fiber
type)
Optical output disabled with static transmit data
Absolute Maximum Ratings
Exceeding any one of these values may destroy the device
immediately.
Package Power Dissipation .......................................................... 1.5 W
Supply Voltage (VCC–VEE) 5 V ....................................................... 6 V
3.3 V .................................................... 4 V
Data Input Levels (PECL).......................................................VCC+0.5 V
Differential Data Input Voltage .......................................................... 3 V
Operating Case Temperature ............................................ 0° C to 70 ° C
Storage Ambient Temperature ....................................... 40 °C to 85°C
Soldering Conditions, Temp/Time
(MIL-STD 883C, Method 2003) ........................................ 250°C/5.5s
DESCRIPTION
Siemens Gigabit Ethernet multimode transceiver is based on the
Physical Medium Depend (PMD) sublayer and baseband medium, type
1000BASE-SX (short wavelength).
The appropriate fiber optic cable is 62.5 µm or 50 µm multimode fiber
with duplex SC connector.
The Siemens Gigabit Ethernet multimode transceiver is a single unit
comprised of a transmitter, a receiver, and an SC receptacle. This design
frees the customer from many alignment and PC board layout concerns.
The module is designed for low cost LAN, WAN, and Gigabit Ethernet
applications. It can be used as the network end device interface in main-
frames, workstations, servers, and storage devices, and in a broad range
of network devices such as bridges, routers, intelligent hubs, and local
and wide area switches.
(1 ±0.1)
.04 ±.039 (0.35 ±0.1)
.014 ±.004
4.675
.184
Optical
Centerline
PC board
(9.8 max)
.386 max
(3.3 ±0.2)
.13 ±.008
(2) .080
12.7
.500
(0.63 ±0.2)
.025 ±.008
(25.25 ±0.05)
.994 ±.002
20.32
.800
123456789
(38.6 ±0.15)
1.52 ±.006
(11 max)
.433 max
(1.4 -0.05)
.055 -.002
●●●●●●●●●
Z
View Z
(Lead cross section
and standoff size)
Rx
Tx
(2.8 max)
.110 max 20.32
.800
20.32
.800
9x (0.8 ±0.1)
.032 ±.004
(1.9 ±0.1)
.075 ±.004
2x
(2.54)
.10 0
(0.6 ±0.1)
.024 ±.004
(8.6 max)
.170 max
(3.8 max)
.150 max
(0.5) typ.
.020 typ.
Top view
Footprint
A
(0.25) typ.
.010 typ.
(2.54)
.10 0
Cutout
2.05
.807
2.5
.984
(15.88 ±0.5)
.625 ±.020
Dimensions in (mm) inches
5 V V23826-K305-C63
3.3 V V23826-K305-C363
DC/DC Coupled Multimode 850 nm 1.3 Gigabit Ethernet
1x9 Transceiver
Preliminary
JUNE 1998
V23826-K305-C63/C363, DC/DC Multimode 850 nm 1.3 Gigabit Ethernet 1x9 Trx
2
Semiconductor Group
This transceiver operates at 1.3 Gbits per second from a single
power supply (+5 V or +3.3 V). The full differential data inputs
and outputs are PECL compatible.
Functional Description of 1x9 Pin Row Transceiver
This transceiver is designed to transmit serial data via multimode
cable.
Functional Diagram
The receiver component converts the optical serial data into PECL
compatible electrical data (RD and RDnot). The Signal Detect (SD,
active high) shows whether an optical signal is present.
The transmitter converts PECL compatible electrical serial data
(TD and TDnot) into optical serial data.
The transmitter contains a laser driver circuit that drives the
modulation and bias current of the laser diode. The currents are
controlled by a power control circuit to guarantee constant output
power of the laser over temperature and aging. The power con-
trol uses the output of the monitor PIN diode (mechanically built
into the laser coupling unit) as a controlling signal, to prevent the
laser power from exceeding the operating limits.
Single fault condition is ensured by means of an integrated auto-
matic shutdown circuit that disables the laser when it detects
transmitter failures. A reset is only possible by turning the power
off, and then on again.
The transceiver contains a supervisory circuit to control the
power supply. This circuit makes an internal reset signal whene-
ver the supply voltage drops below the reset threshold. It keeps
the reset signal active for at least 140 milliseconds after the
voltage has risen above the reset threshold. During this time the
laser is inactive.
An ISM-Shut-Down (Input Signal Monitor) disables laser if a con-
stant logic low is present at the input.
Laser
Driver
Power
Control
Receiver
o/e
o/e
Laser
e/o
RX Coupling Unit
TD
TD
RD
RD
SD
Laser Coupling Unit
Multimode Fiber
LEN
Monitor
Signal Monitor and
Automatic Shut-Down
TECHNICAL DATA
The electro-optical characteristics described in the follow-
ing tables are valid only for use under the recommended
operating conditions.
Recommended Operating Conditions
Notes
1. For VCC–VEE (min., max.). 50% duty cycle. The supply current does
not include the load drive current of the receiver output. Add max.
45 mA for the three outputs. Load is 50 to VCC–2 V.
2. Data inputs are DC coupled.
Transmitter Electro-Optical Characteristics
Notes
1. Into multimode fiber, 62.5 µm or 50 µm diameter.
2. Laser power is shut down if power supply is below VTH and swit-
ched on if power supply is above VTH after tRES.
Parameter Symbol Min. Typ. Max. Units
Case Temperature TC070°C
Power Supply
Voltage
K305-C63 VCC
VEE
4.75 5.0 5.25 V
K305-C363 3.1 3.3 3.5
Supply
Current(1)
K305-C63 ICC Tbd Tbd mA
K305-C363 Tbd Tbd
Transmitter
Data Input Low Voltage(2) VIL–VCC -1950 -1475 mV
Data Input High Voltage VIH–VCC -1100 -720
Receiver
Input Center Wavelength λC770 860 nm
Transmitter Symbol Min. Typ. Max. Units
Launched Power
(Average)(1)
PO–9.5 –4 dBm
Center Wavelength λC830 850 860 nm
Spectral Width (RMS) σλ0.85
Relative Intensity Noise RIN –117 dB/Hz
Extinction Ratio (Dynamic) ER 9 dB
Reset Threshold(2) VTH 2.9 V
Reset Time Out(2) tRES 140 240 560 ms
Rise/Fall Time, 20%–80% tR, tF0.26 ns
Coupled Power Ratio CPR 9dB
V23826-K305-C63/C363, DC/DC Multimode 850 nm 1.3 Gigabit Ethernet 1x9 Trx
3
Semiconductor Group
LASER SAFETY
This multimode Gigabit Ethernet transceiver is a Class 1 laser
product. It complies with IEC 825-1 and FDA 21 CFR 1040.10 and
1040.11. The transceiver must be operated under recommended
operating conditions.
Caution
The use of optical instruments with this product will
increase eye hazard!
General Restrictions
Classification is valid only if the module is operated within the
specified temperature and voltage limits. The system using the
module must provide power supply protection that guarantees
that the system power source will cease to provide power if the
maximum recommended operation limit or more is detected on
the +3.3 V/+5 V at the power source. The case temperature of
the module must be in the temperature range given in the
recommended operating limits. These limits guarantee the
laser safety.
Usage Restrictions
The optical ports of the modules shall be terminated with an
optical connector or with a dust plug.
Note
Failure to adhere to the above restrictions could result in a modifica-
tion that is considered an act of “manufacturing,” and will require,
under law, recertification of the modified product with the U.S. Food
and Drug Administration (ref. 21 CFR 1040.10 (i)).
Laser Data
Required Labels
Laser Emission
Wavelength 850 nm
Total output power (as defined by IEC: 50 mm
aperture at 10 cm distance)
<400 µW
Total output power (as defined by FDA: 7 mm
aperture at 20 cm distance)
<70 µW
Beam divergence 12°
Class 1 Laser Product
IEC
Complies with 21 CFR
1040.10 and 1040.11
FDA
Indication of laser
aperture and beam
Receiver Electro-Optical Characteristics
Notes
1. Minimum average optical power at which the BER is less than
1 x 10E–12. Measured with a 271 NRZ PRBS and ER=9 dB.
2. An increase in optical power above the specified level will cause the
SIGNAL DETECT output to switch from a Low state to a High state.
3. A decrease in optical power below the specified level will cause the
SIGNAL DETECT to change from a High state to a Low state.
4. PECL compatible. Load for Data outputs is 50 into VCC–2V. Mea-
sured under DC conditions. For dynamic measurements a tolerance
of 50 mV should be added. For SD Output: Load is 510/270 (5 V/
3.3 V) to GND/VEE.
Pin Description 1x9 Pin Row
Receiver Symbol Min. Typ. Max. Units
Sensitivity
(Average Power)(1)
PIN –19 17 dBm
Saturation
(Average Power)
PSAT 0
Signal Detect
Assert Level(2)
PSDA –24 20
Signal Detect
Deassert Level(3)
PSDD –30 27
Signal Detect
Hysteresis
PSDA
PSDD
3dB
Signal Detect Assert Time tASS Tbd µs
Signal Detect
Deassert Time
tDAS Tbd
Output Low
Voltage(4)
K305-C63 VOL–VCC –1950 –1620 mV
K305-C363 Tbd Tbd
Output High
Voltage(4)
K305-C63 VOH
VCC
–1100 –720
K305-C363 Tbd Tbd
Output Data Rise/Fall
Time, 20%–80%
t
R
, t
F
375 ps
Return Loss
of Receiver
ARL 12 dB
Pin Name Level Pin # Description
RxVEE Rx Ground Power
Supply
1 Negative power supply,
normally ground
RD Rx Output
Data
PECL
Output
2 Receiver output data
RDn Rx Output
Data
PECL
Output
3 Inverted receiver
output data
SD RX Signal
Detect
PECL
Output
active high
4 A high level on this out-
put shows that there is
an optical signal
RxVCC Rx 3.3 V/5 V Power
Supply
5 Positive power supply,
3.3 V/5 V
TxVCC Tx 3.3 V/5 V Power
Supply
6 Positive power supply,
3.3 V/5 V
TDn Tx Input
Data
PECL Input 7 Inverted transmitter
input data
TD Tx Input
Data
PECL Input 8 Transmitter input data
TxVEE Tx Ground Power
Supply
9 Negative power supply,
normally ground
Case Ground Mech.
Support
S1/2 Support stud (floating)
Siemens Microelectronics, Inc. • Optoelectronics Division • 19000 Homestead Road • Cupertino, CA 95014 USA
Siemens Semiconductor Group • Fiber Optics • Wernerwerkdamm 16 • Berlin D-13623, Germany
Siemens K.K. • Fiber Optics • Takanawa Park Tower • 20-14, Higashi-Gotanda, 3-chome, Shinagawa-ku • Tokyo 141, Japan
www.smi.siemens.com/opto.html (USA) • www.siemens.de/Semiconductor/products/37/376.htm (Germany)
Regulatory Compliance
Feature Standard Comments
Electrostatic Discharge (ESD)
to the Electrical Pins
MIL-STD 883C
Method 3015.4
Class 1 (>1000 V)
Immunity:
Electrostatic Discharge (ESD) to the Duplex
SC Receptacle
EN 61000-4-2
IEC 1000-4-2
Discharges of ±15kV with an air discharge probe on the
receptacle cause no damage.
Immunity:
Radio Frequency
Electromagnetic Field
EN 61000-4-3
IEC 1000-4-3
With a field strength of 10 V/m rms, noise frequency ranges
from 10 MHz to 1 GHz. No effect on transceiver performance
between the specification limits.
Emission:
Electromagnetic Interference (EMI)
FCC Class B
EN 55022 Class B
CISPR 22
Noise frequency range: 30 MHz to 1 GHz
APPLICATION NOTE FOR 850 NM GIGABIT ETHERNET 1X9 TRANSCEIVER
C6
C7
VCSEL
Driver
Signal
Detect
Limiting
Amplifier
Pre-
Amp
RD–
RD+
TX+
TX–
Serializer/
Deserializer
Gigabit
Transceiver
Chip
RD–
ECL/PECL
Driver
Receiver
PLL etc.
Siemens Transceiver
V23826-K305-C63/C363
DC DC Option
1
2
3
4
5
6
7
8
9
SD to upper level
ECL-Compatible
TXGND
TxD
TxD
VCCTx
VCCRx
SD
RxD
RxD
RxGND
VCC
R4
R5
L1
L2
C2
C1
R6
R2
R3
R1
C3
C4
C5
VCC SerDes
3.3 V
VCC
Optics
RD+
R8
R10
R7
R9
VCC
Optics
C1/2/3 = 4.7 µF
C4/5/6/7 = 10 nF
L1/2 = 1 µH
R1 = 100 (depends on SerDes chip used and desired line termination) (50 Strip line)
R2/3 = 270 (150 )
R4/5 = depends on SerDes chip used
R6 = 510 (270 )
R7/8 = 68
R9/10 = 191 (in brackets resistors for 3.3 V transceivers)
This Application Note assumes Fiber Optic Transceivers using 5 V
power supply and SerDes Chips using 3.3 V power supply. It also
assumes self biasing at the receiver data inputs (RD+/RD-) of the
SerDes chip. Refer to the manufacturer data sheet for other applica-
tions. 3.3 V-Transceivers can be directly connected to SerDes-Chips
using standard PECL Termination network.
Value of R1 may vary as long as proper 50 termination to VEE or
100 differential is provided. The power supply filtering is required
for good EMI performance. Use short tracks from the inductor
L1/L2 to the module VCCRX/VCCTX.
The transceiver contains an automatic shutdown circuit. Reset is
only possible if the power is turned off, and then on again. (VCCTX
switched below VTH). Application Board available on request.