Datasheet 1340TMPC, 1340TBPC, 1340TAPC, 1340FNPC, 1340FMPC Datasheet (AGERE)

Data Sheet

January 2000

1340-Type Lightwave Receiver

Operating at 1.1 µm through 1.6 µm wavelengths and at
155 Mbits/s, 622 Mbits/s, or 1. 2 5 G bit s /s , the versatile
1340-Type Rec eiv er is man ufactured in a 20-pin, plastic D IP
with a multimode fiber pigtail.

Features

■

Backward compatible with 1310 receiver family

■

Space-saving, self-contained, 20-pin plastic DIP

■

Silicon-based ICs

■

Single 5 V power supply operation including photo­current monitor capability

■

Exceeds all SONET (GR-253-CORE) and ITU-T
G.958 jitter requirements

■

Wide dynamic range

■

Qualified to meet the intent of Telcordia Technolo­gies

* reliability practices

■

Operates at data rates of 155 Mbits/s,
622 Mbits/s, or 1.25 Gbits/s

■

Positive ECL (PECL) data outputs

■

CMOS (TTL) link-status flag output

■

Operation at 1.3 µm or 1.55 µm wavelengths

■

Operating case temperature range of
–40 °C to +85 °C

Applications

■

Telecommunications:
—Inter- and intraoffice SONET/ITU-T SDH
—Subscriber loop
—Metropolitan area networks

■

High-speed data communications

Description

The 1340-Type receiver is designed for use in trans­mission systems or medium- to high- speed data
communications applications at data rates up to

1.25 Gbits/s. Compact packaging, along with wide
dynamic range, makes these receivers ideal for both
telecommunications and data communications appli­cations.

The following three versions of the receiver are avail­able:

■

SONET/SDH compliant with OC-3/STM-1

■

SONET/SDH compliant with OC-12/STM-4

■

1.25 Gbits for data applications.

* Telcordia Technologies is a trademark of Telcordia Technologies,

Inc.

22 Agere Systems Inc.

Data Sheet

January 2000

1340-Type Lightwave Receiver

Description

(continued)

The SONET/SDH versions of the receiver are fully
compliant with the latest issue of Telcordia Tec hnolo-
gies GR-253- CORE and the most recent issues of ITU
recommendations G.957 and G.958. The 1340-Type
receiver requires only a single 5 V power supply for
operation. All versions of the receiver are characterized
for operation ove r the case operating range of –40 °C
to +85 °C at the appropriate data rate for each version.

Manufactured in a 20-pin DIP, the receivers use a pla­nar, rea r illuminated InGaAs P IN photode tector that
allows these receivers to be used at wavelengths from

1.1 µm to 1.6 µm. The photocurrent output of the PIN
detector is amplified and converted to a voltage by a
silicon amplifi er. A silic on quantizer provides additional

signal amplification, data threshold detection, and
PECL data outputs. The incoming optical signal is cou­pled into the receiver through a 62.5 µm core multi­mode fiber pigtail. The outer j acket diameter of the
pigtail is 900 µm. The receiver can be ordered with the
pigtail terminated in a n FC/PC, SC, or ST

®

optical con­nector. Other connectors are a vailab le on special order .
See your Agere account representative for ordering
conditions and inform ation.

The receiver has differential PECL data outputs and,
depending on the version selected, either differential
PECL link status flag or complementary CMOS link
status flag outputs. The link status flag outputs indicate
the presence or absence of a minimum acceptable
level of optical input signal.

1-414(F)

Figure 1. Block Diagram

GaAs

PREAMPLIFIER

FILTER

InGaAs

PIN

Si

COMPARATOR

DATA

DATA

FLAG

FLAGV

CC

V

PIN

FILTER

Data Sheet
January 2000

1340-Type Lightwave Receiver

Agere Systems Inc. 3

Description

(continued)

To help ensure high product reliability and custom er
satisfaction, Agere is committed to an intensive quality
program that star ts in the design phase and proceeds
through the manufacturing and shipping process. Opto­electronics subsystems are qualified to Agere internal
standards using MI L-ST D-883 te st methods and pro­cedures and sampling techniques consistent with Tel-
cordia Technologies requirements. The 1340 receiver
qualification program meets the intent of Telcordia
Technologies TR-NWT-000468 and TA-TSY-000983.

Application Information

The 1340 receive r i s a highly sensitive fiber-optic
receiver. Although the data outputs are digital logic lev­els (PECL), the device should be thought of as an ana­log component. When laying out the printed-wiring
board (PWB), the 1340 receiver should be given the
same type of consideration one would give to a sensi­tive analog component.

At a minimum, a double-sided printed-wiring board with
a large component-side ground plane beneath the
receive r must be used. In appli cations tha t incl ude
many other high-speed devices, a multilayer PWB is
highly recommended. T his permits the placement of
power and ground connections on separate layers,
which helps minimize the coupling of unwanted signal
noise into the power supplies of the receiver.

Layout Considerations

A fiber-optic receiver employs a very high-gain, wide­bandwidth transimpedance amplifier. The amplifier
detects and amplifies signals that are only tens of nA in
amplitude. Any unwanted signal currents that couple
into the receiver circuitry cause a decrease in the
receiver’s sensitivity and can also degrade the perfor­mance of the receiver’s loss of signal (FLAG) circuit.

To minimize the coupling of unwanted noise into the
receiver, route high-level, high-speed signals such as
transmitter inputs and clock lines as far away as possi­ble from the receiver pins. If this is n ot po ssible, then
the PWB layout engineer should consider interleaving
the receiver signal and flag traces with ground traces in
order to provide the required isolation.

Noise that couples into the receiver through the power
supply pins can also degrade device performance. The
application schematics, F igures 3—5, show recom­mended power supply filtering that helps minimize
noise coupling into the receiver. The bypass capacitors
should be high-quality ceramic devices rated for RF
applications. They should be surface-mount compo­nents placed as close as possible to the receiver power
supply pins. The ferrite bead should have as high an
impedance as p ossible in the frequency range that is
most likely to cause problems. This will vary for each
application and is dependent on the signaling frequen­cies present on the application circuit card. Surface­mount, high-impedance beads are available from sev­eral manufacturers.

Data and Flag Outputs

The data outputs of the 1340 receiver are driven by
open-emitter NPN transistors which have an output
impedance of approximately 7 Ω. Each output can pro­vide approximately 50 m A maximum output current.
Due to the high switching speeds of ECL outputs,
transmission line design must be us ed to interconnect
components. To ensure o ptimum signal fidelity, both
data outputs (DATA and DATA

) should be terminated
identically . The signal lines connecting the data outputs
to the next device should be equal in length and should
have matched impedances.

Controlled impedance stripline or microstrip construc­tion must be used to preserve the quality of the signal
into the next component and to minimize reflections
back into the receiver. Excessive ringing due to reflec­tions caused by improperly terminated signal lines
makes it difficult for the component receiving these sig­nals to decipher the pr oper logic levels and may cause
transitions to occur where none were intended. Also , by
minimizing high frequency ringing due to reflections
caused by improperly designed and terminated signal
lines, possible EMI problems can be avoided. The
applications sections in the Signetics

*

ECL 10K/100K

Data Manual or the National Semiconductor

†

ECL
Logic Databook and Design Guide provide excellent
design information on ECL interfacing.

* Signetics is a registered trademark of Signetics Corp.
† National Semiconductor is a registered trademark of National

Semiconductor Corporation.

44 Agere Systems Inc.

Data Sheet

January 2000

1340-Type Lightwave Receiver

Data and Flag Outputs

(continued)

The FLAG and FLAG

outputs of the OC-3/STM-1
155 Mbits/s version of the 1340 receiver are PECL
logic levels dr iven by open emitter transistors wi th the
same characteristics as the data outputs. These out­puts must be properly terminated in order to obtain the
correct logic levels. Since the FLAG function is basi­cally a dc switch that indicates the loss of optical input
signal, it can be interfaced to much slower TTL or
CMOS logic circuits.

The circuit shown in Figure 2 provides one example of
how to create a TTL logic output from the PECL FLAG

output signal. The outputs of the LT1016 are TTL-com­patible and provide both true and inverted logic levels.
The Q output of this circuit will be a TTL high (>2.5 V)
when the 1340 is receiving an optical signal gr e at er
than the FLAG switching threshold and will be a TTL
low (<0.4 V) whenever the optical s ignal is absent or is
below the FLAG switching threshold. The FLAG and
FLAG

outputs of the OC-12/STM- 4 and 1.25 Gbits/s
receivers are 5 V TTL logic level compatible. The FLAG
output is provided directly by the comparator IC. How­ever, the FLAG output is derived from the FLAG

output

through an inverter. Excessive loading of the FLAG

out-

put can cause the FLAG output to malfunction.

1-800(C).a

* Part available from Linear Technology Corporation of Milpitas, CA 95035.

Figure 2. Converting PECL FLAG Outputs to TTL

11

12

14

10 k•

TTL (TRUE)

TTL (INVERTED)

LT1016*

1340

RX

FLAG

FLAG

+5 V +5 V

10 k•

+

–

Q

Q

Agere Systems Inc. 5

Data Sheet
January 2000

1340-Type Lightwave Receiver

Pin 10

Pin 10 on the 1340-Type receiver is a not internally
connected (NIC) pin. This definition allows the 1340 to
be used in most customer 20-pin receiver module
applications. Customer’s printed-wiring boards that are
designed with ground, +5 V, –5 V, or no connection to
this pin are all acceptable options. For those applica­tions that req uire monitoring the photocurrent of the
PIN photodetector for power monitoring purposes,
there are ve rsi ons of the 1340 that require +5 V or –5 V
applied to Pin 10. Check Tables 4 and 5 for ordering
information.

Recommended User Interface

The 1340 receiver is designed to be op erated from a
5 V power supply and provides raised or pseudo-ECL
(PECL) data outputs. Figures 3 and 4 show two possi­ble application circuits for the 1340 receiv er. Figure 3
represents an application for the version with PECL
FLAG outputs while Figure 4 shows a possible applica­tion for the version with the TTL-compatible FLAG
outputs.

In both instances, the DATA outputs are terminated with
a Thévenin equivalent circuit, which provides the equiv­alent of a 50 Ω load terminat ed to (V

CC – 2 V).

A single 50 Ω resistor terminated to (V

CC

– 2 V) could
also be used, but this requi res a second power supply.
Other methods of ter mina tin g ECL-type outputs are
discussed in the references previously mentioned.

Figure 5 shows an example of a circuit that can be
used to interface the P ECL outputs of the 1340 receiver
with a device which requires true, negative voltage ECL
inputs. The 100314 is an ECL line receiver and is
shown here only as an example to demonstrate this
coupling procedure. The DATA lines are terminated in a
50 Ω equivalent impedance but are ac-coupled to the

100314. The capacitive coupling isolates and permits
level shifting of the positive DATA outputs of the
receiver to the proper negative level required by the
inputs of the 100314. The V

BB

output of the 100314
provides the reference voltage required to center t he
voltage swing of the DATA signals aroun d the input
switching t h reshold of the 100314. The Thévenin
equivalent of the 166 Ω and 250 Ω resist or pair is
100 Ω, which, in parallel with the 100 Ω resistor con-
nected to V

BB

, results in a 5 0 Ω equivalent impedance
for the load on each of the data lines. Alternatively, if
there is no V

BB

reference available, a second pair of
166 Ω/250 Ω resistor networks could be used on the
data lines on the 100314 side of the coupling capacitor.

* 50 Ω to (VCC – 2) V.
† DATA and

DATA

are 50 Ω impe dance transm ission lin es ; both lines can be ac- or dc- c o up led into the next devi ce.

‡ Fair-Rite Pro du cts Corp o rat io n pa rt numb er 2743 037447 o r e q uivalent.
Note: All unused outputs must be terminated as shown. All resistors are 1/8 W, thin-film, ceramic chips. All capacitors are

25 Vdc, ceramic X7R , or equivalent.

Figure 3. Interfacing to the 155 Mbits/s 1340 Receiver

1340

0.1 µF0.1 µF

124 •

9

7

11

12

14

0.1 µF0.1 µF

82 • 82 •

2.2 µF

†

FLAG*

124 • 124 •

FLAG*

+5.0 V

82 • 82 •

124 •

DATA

†

DATA

†

FERRITE
BEAD

‡

1-500(C).d

Data Sheet

January 2000

1340-Type Lightwave Receiver

6 Agere Systems Inc.

Recommended User Interfaces

(continued)

* TTL (CMOS) compatible level.
† DAT A and DATA

are 50 Ω impedance transmission lines; both lines can be ac- or dc-coupled into the next device.

‡Fair-Rite Products Corporation part number 2743037447 or equivalent.

Figure 4. Interfacing to the 622 Mbits/s and 1.25 Gbits/s 1340 Receivers

1-572(C).b

*50 Ω to (VCC – 2) V.
†50 Ω to –2 V. DATA and DATA

are 50 Ω impedance transmission lines.

‡Fair-Rite Products Corporation part number 2743037447 or equivalent.

Figure 5. Interfacing the 155 Mbits/s 1340 Receiver to a True ECL Circuit

1340

0.1 µF 0.1 µF

124 •

9

7

11

12

14

2.2 µF

†

0.1 µF

FLAG*

FLAG*

+5.0 V

82 • 82 •

124 •

DATA

†

DATA

†

FERRITE

‡

BEAD

14

12

11

0.1 µF

124 •

100 •

100 •

1340

0.1 µF

0.1 µF

82 •

124 •

82 •

124 •

0.1 µF

FLAG*

FLAG*

9*

7*

2.2 µF

†

+5 V

0.1 µF

124 •

–
+

16

17

19

6, 7

18

11

10

100314

0.1 µF

0.1 µF

0.1 µF

10 µF

D

Q

D

Q

0.1 µF

0.1 µF

82 • 82 •

V

EE

V

BB

DATA

†

DATA

†

166 •

250 •

166 •

250 •

FERRITE
BEAD

‡

V

EE

1-500(C).c

Data Sheet
January 2000

1340-Type Lightwave Receiver

Agere Systems Inc. 7

Pin Information

Table 1. Pin Descriptions

* Pins designated as no use r connection are not connected internally wi thin the receiver. H owever, to allow for fut ure functional upgrades, it is

recomm e nd e d th at t h e us er n ot m ake any c onne ct i on s to these pin positions.

† The lin k-s t a tu s fla g is a log ic o utput that in di cates the p re s ence or absence of a minimum acceptable level of optical input. A logic high on

FLAG indi cates the presence of a valid optical signal.

Handling Precautions

Mounting and Connections

The pigtail consists of a 39 in. ± 4 in. (1 m ± 10 cm), 62.5 µm core/125 µm cladding multimode fiber. The standard
fiber has a 0.036 in. (914 µm) di ameter tight-buffered outer jacket. The minimum fiber bending radius during opera­tion is 1.0 in. (25.4 mm).

Pin Number Description

1 Ground
2 Ground
3 Ground
4 Ground
5 No User Connection*
6 Ground
7DATA
8 Ground
9DATA

10 NIC or Optional V

PIN

11 Vcc (5 V)
12 FLAG

†

13 Ground
14 FLAG
15 Ground
16 Ground
17 No User Connection*
18 No User Connection*
19 No User Connection*
20 No User Connection*

Data Sheet

January 2000

1340-Type Lightwave Receiver

8 Agere Systems Inc.

Electrostatic Discharge

Caution: This device is susceptible to damage as a result of electrostatic discharge (ESD). Take proper

precautions during both
handling and testing. Follow EIA* Standard EIA-625.

Although protection circuitry is designed into the device, take proper precautions to avoid exposure to ESD.
Agere employs a human-body model (HBM) for ESD susceptibility testing and protection-design evaluation. ESD

voltage thresholds are dependent on the critical parameters used to define the model. A standard HBM (resistance
= 1.5 kΩ, capacitance = 100 pF) is widely used and, therefore, can be used for comparison purposes. The HBM
ESD threshold established for the 1340 receiver is ± 1000 V.

Receiver Processing

The 1340-type receiver devices can withstand normal wave-soldering processes. The complete receiver module is
not hermetically sealed; therefore, it should not be immersed in or sprayed with any cleaning solut ion or solvents.
The process cap and fiber pigtail jacket deformation temperature is 85 °C. The receiver pins can be wave-soldered
at maximum temperature of 250 °C for 10 seconds.

Installation Considerations

Although the receiver features a robust design, care should be used duri ng handling. The optical connector should
be kept free from dust, and the process cap should be kept in place as a dust cover when the device is not con­nected to a cable. If contamination is present on the optical connector, the use of canned air with an extension tube
should remove any debris. Other cleaning procedures are identifi ed in the technical note, Cleaning Fiber-Optic
Assemblies (TN95-010LWP).

* EIA is a registered trademark of Electronic Industries Association.

Data Sheet
January 2000

1340-Type Lightwave Receiver

Agere Systems Inc. 9

Absolute Maximum Ratings

Stresses in excess of the absolute maximum ratings can cause permanent damage t o the device. These are abso­lute stress ratings only. Functional operation of the device is not implied at these or any other conditions in excess
of those given in the operations section of the data sheet. Exposure to absolute maximum ratings for extended
periods can adversely affect device reliability.

Operating Characteristics

Minimum and maximum values specified over operating case temperature range and end-of-life (EOL).
Typical values are measured at beginning-of-life (BOL) room temperature unless otherwise noted.

Table 2. Optical Characteristics

* For 1 x 10

–10

BER with an optical input using a 2

23

– 1 pseudorandom word having a 50% average duty cycle.

Parameter Symbol Min Max Unit

Supply Voltage V

CC —5.5 V

Operating Case Temperature Range T

C

–40 85 °C

Storage Case Temperature Range T

stg

–40 85 °C
Lead Soldering Temperature/Time — — 250/10 °C/s
Operating Wavelength Range λ 1.1 1.6 µm
Minimum Fiber Bend Radius — 1.0 (25.4) — in. (mm)

Parameter Symbol

Data Rate

(Mbits/s)

Min Typ

*

Max Unit

Measured Average Sensitivity

*

P

R

155
622

1250

—
—
—

–38
–32
–28

–36
–29
–24

dBm
dBm
dBm

Maximum Input Power

*

P

MAX

155
622

1250

–3.0
–6.0
–3.0

0
–3.0
–2.0

—
—
—

dBm
dBm
dBm

Link Status Switching Threshold:

Decreasing Light Input

Increasing Light Input

Hysteresis

LST

D

LST

I

HYS

155
622

1250

155
622

1250

All Data

Rates

–53.0
–45.0
–36.0

–52.5
–45.5
–35.5

0.5

–40
–34

–31.0

–38
–31

–29.0

3.0

–36.0
–28.0
–26.0

–35.5
–27.5
–25.5

6.0

dBm
dBm
dBm

dBm
dBm
dBm

dBm

Detector Responsivity R All Data

Rates

0.7 0.8 1.2 A/W

Data Sheet

January 2000

1340-Type Lightwave Receiver

10 Agere Systems Inc.

Operating Characteristics

(continued)

Table 3. Electrical Characteristics

* Customers have the option for either a +5 V or –5 V supply.
† M ea sured from V

CC with a 50 Ω load to (VCC – 2) V.

‡ Internally te r m ina t e d C MOS outp ut.

Qualification Tests and Reliability

To help ensure high product reliabil i t y and custome r sati s f a ction, Agere is committed to an intensive qual i ty pro­gram that starts in the design phase and proceeds through the manufacturing process. Optoelectronics modules
are qualified to Agere internal standards using MIL-STD-883 test methods and procedures and using sampling
techniques consistent with Telcordia Techno logie s requirements. The 1340-Type receivers have undergone an
extensive and rigorous set of qualification tests. This qualification program fully meets the intent of Telcordia Tech-

nologies

reliability practices TR-NWT-000468 and TA-NWT-000983. In addition, the design, development, and man­ufacturing facility of Agere’s Optoelectronics unit has been certified to be in full compliance with the late st ISO*-
9001 Quality System Standards.

* ISO is a registered trademark of The International Organization for Standardization.

Parameter Symbol Min Typ Max Unit

dc Power Supply Voltage V

CC

4.75 5.0 5.25 V

PIN Photodetector Supply Voltage (Pin 10)* V

PIN

V

PIN

4.75

–5.25

5.0

–5.0

5.25

–4.75

V
V

Power Supply Current I

CC

I

PIN

—
—

80

—

150

1

mA
mA

Output Data V oltage:

†

Low
High

V

OL

V

OH

V

CC

– 1.81

V

CC

–1.025

V

CC

– 1.70

V

CC

– 0.95

V

CC

– 1.62

V

CC

– 0.88

V
V

Output Rise Time/Fall Time:

OC-3/STM-1 Versions
OC-12/STM-4 Versions

t

R/tF

tR/tF

—
—

700
350

1400

400

ps
ps

Output Flag Voltage:

OC-3/STM-1 Versions:

‡

Low
High

OC-12/STM-4 Versions:

‡

Low
High

V

FL

V

FH

V

FL

V

FH

—

V

CC

– 1.025

0

V

CC

– 0.5

V

CC

– 1.90

V

CC

– 1.0

—
—

V

CC

– 1.65

—

0.5

V

CC

V
V

V
V

Output Data Current:

†

Low
High

I

OL

I

OH

—
—

5

20

50
50

mA
mA

Output Flag Current:

OC-3/STM-1 Versions:

Low
High

OC-12/STM-4 Versions:

Low
High

I

OL

I

OH

I

OL

I

OH

—
—

0
0

5

20
10

10

50
50

15
15

mA
mA

mA
mA

Data Sheet
January 2000

1340-Type Lightwave Receiver

Agere Systems Inc. 11

Outline Diagram

Dimensions are in inches and (millimeters). Unless noted otherwise, tolerances are 0.005 in. (0.127 mm).

1-988(C)

1.339

(34.01)

0.968

(24.58)

0.635

(16.14)

0.147
(3.73)

TOP VIEW

PIN 1 INDICATOR

0.125
(3.17)

0.110
(2.80)

0.100
(2.54)

0.900

(22.86)

0.350 (8.89)

0.400

(10.16)

PIN 20PIN 11

PIN 1

PIN 10

0.018
(0.46)

1340-Type Lightwave Receiver Advance Data Sheet
for OC-1,3/STM-1 January 2000

Agere S ystems In c. re se rves th e right to make changes to the product(s) or information contained herein without notice. No liabi lity is assumed as a result of their use or application. ST is a
registered trademark of Agere Systems Inc.

Copyright © 2000 Agere Systems Inc.
All Rights Reserved
Printed in U.S.A.

Januar y 20 00
DS00-098OPTO (Replaces DS99-072LWP)

For additional information, contact your Agere Systems Account Manager or the following:
INTERNET: http://www.agere.com
E-MAIL: docmaster@agere.com
N. AMERICA: Agere Systems Inc., 555 Union Boulev ar d, Room 30L-15P-BA, Allento wn, P A 18109-3286

1-800-372-2447, FAX 61 0- 712- 4106 (In CANADA: 1-800-553-2448, FAX 610-712-4106)

ASIA: Agere Systems Hong Kong Ltd., Suites 3201 & 3210-12, 32/F, Tower 2, The Gateway, Harbour City, Kowloon

Tel. (852) 3129-2000, FAX (852) 3129-2020
CHINA: (86) 21-5047-1212 (Shanghai), (86) 10-6522-5566 (Beijing), (86) 755-695-7224 (Shenzhen)
JAPAN: (81) 3-5421-1600 (Tokyo), KOREA: (82) 2-767-1850 (Seoul), SINGAPORE: (65) 778-8833, TAIWAN: (886) 2-2725-5858 (Taipei)

EUROPE: Tel. (44) 7000 624624, FAX (44) 1344 488 045

Ordering Information

Table 4. OC-3/STM-1 Receiver Versions

Table 5. OC-12/STM-4 Receiver Versions

Table 6. 1.25 Gbits/s Receiver Versions

Table 7. Rela ted Products

Device Code Connector Pin 10 Requirements Comcode

1340FMPC FC-PC No

Internal

Connection

108162322
1340CMPC SC 108354408
1340TMPC ST 108572264

1340FAPC FC-PC Requires +5 V or –5 V

(Used for photocurrent

monitoring)

108468687
1340CAPC SC 108359175

1340TAPC ST 108572249

Device Code Connector Pin 10 Requirements Comcode

1340FNPC FC-PC No

Internal

Connection

108155680
1340CNPC SC 108354416
1340TNPC ST 108155755

1340FBPC FC-PC Requires +5 V or –5 V

(Used for photocurrent

monitoring)

108155672
1340CBPC SC 108468679

1340TBPC ST 108572256

Device Code Connector Pin 10 Requirements Comcode

1340FCPC FC-PC Requires

+5 V or –5 V

108400342
1340CCPC SC 108400334

Description Document Number

1241/1243/1245-Type Receivers for SONET/SDH Applications DS99-073LWP
1345-Type Receiver with Clock Recovery and Data Retiming DS00-099OPTO

Data Sheet

January 2000

1340-Type Lightwave Receiver