EMCORE’s Model 1933 DFB lasers offer a low cost solution for linear fiber optic
links. These components can be cooled with external thermo-electric coolers for
high stability, or run without TEC’s to reduce power consumption. The DFB laser
builds upon Ortel’s long history of high performance, leading edge designs in
CATV, wireless, and high speed digital applications. The laser diode devices are
packaged in a compact hermetic assembly together with monitor photodiode and
isolator, for flexible integration into various transmitter configurations.
Performance Highlights
Parameters
Min
-40
3
5
(1)
(1)
Typical
-
-
-
-
Max
85
5.9
4000
-
Units
C
dBm
MHz
dB
dBc
dBc
Applications
Video Signal Distribution in HFC and
FTTx Nodes
Signal Distribution in L-Band and
Wireless Remoting Links
High Linearity, Low Power Fiber Links
Operating Case Temperature Range
Optical Output Power
Frequency Range
Carrier-to-Noise Ratio (79 channels)
Composite Triple Beat (79 channels)
Center Wavelength
(1)
(1)
(1)
51
Composite Second Order (79 channels)
(1)
1300
35
30
-
-
-
1320
-
-
nm
dB
dB
Features
Linear DFB Laser Design
Ouput Power Up to 10 dBm Available
Bandwidth > 4000 MHz
RoHS Compliance
Optical Isolator
Low Power Consumption
Monitor Photodiode
Optical Return Loss
Side Mode Suppression Ratio, CW
1. Performance at Tcase = 25°C
| REV 2012.08
Information contained herein is deemed reliable and accurate as of the issue date. EMCORE reserves the right to change the design or specification at any time without notice.
1933 F/R/W Coaxial DFB Laser Diode
1310 nm, Wide Bandwidth 5 MHz – 4000 MHz
DATASHEET | AUGUST 2012
FIBER OPTICS
Absolute Maximum Ratings
1
Stresses in excess of the absolute maximum ratings can cause permanent damage to 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
operational sections of the data sheet. Exposure to absolute maximum ratings for extended periods can adversely affect
device reliability.
Parameters
Storage Temperature
Operating Case Temperature
Laser Diode Forward Current
Laser Diode Reverse Voltage
Photodiode Forward Current
Photodiode Reverse Voltage
Average RF Input Power
Lead Soldering Temperature/Time
Relative Humidity
ESD
Symbol
T
STG
T
OP
I
OP
V
R
I
MPD
V
MPD,R
PIN
-
RH
-
Condition/Notes
Non-Operating
Continuous
CW
Continuous
Continuous
Continuous
60 Seconds
-
Continuous
Human Body Model
Min
-40
-40
-
-
-
-
-
-
-
-500
Max
85
85
150
1.0
2
10
62
260/10
85
+500
Unit
o
o
C
C
mA
V
mA
V
dBmV
o
C/sec
%
V
1. Absolute maximum data are limited to system design only; proper device performance is not guaranteed over rating
listed above. Operation beyond these maximum conditions may degrade device performance, lead to device failure,
shorter lifetime, and will invalidate the device warranty.
Electrical/Optical Characteristics
Parameters
Optical Output Power
Symbol
Conditions/Notes
1933R opt model: 3 – 6dBm
Min
3
5
6
9
10
-
-
-
Typ
-
-
-
-
-
8
13
-
1.17
-
-
4
-
-
-
-
Max
4.9
5.9
8.9
9.9
11.9
15
20
80
1.8
0.3
1.2
8
2000
50
1320
-150
Unit
P
O
1933W opt model: 3 – 10dBm
1933F opt model: 3 – 10dBm
dBm
Threshold Current
Laser Bias Current
Forward Voltage
Slope Efficiency
Thermal Slope Efficiency
Laser Input Impedance
MPD Current
MPD Dark Current
Center Wavelength
Relative Intensity Noise
I
TH
I
OP
V
F
SE
TSE
Z
I
MPD
I
D
c
RIN
T
case
= 25ºC
T
case
= 45ºC
mA
mA
V
mW/mA
-
A
nA
nm
dB/Hz
I
op
T
case
= 25ºC, I
op
SE(Tc)/SE(25ºC)
T
case
= -20ºC to 85ºC
-
V
MPD
= 5V, I
op
V
MPD
= 5V, I
op
= 0
T
case
= 25ºC
I
op
CW, I
op
,
T
case
= 25ºC
5 MHz - 1002 MHz
-
0.07
0.4
2
200
-
1300
-
| REV 2012.08
Information contained herein is deemed reliable and accurate as of the issue date. EMCORE reserves the right to change the design or specification at any time without notice.
1933 F/R/W Coaxial DFB Laser Diode
1310 nm, Wide Bandwidth 5 MHz – 4000 MHz
DATASHEET | AUGUST 2012
FIBER OPTICS
Electrical/Optical Characteristics
(continued)
Parameters
Tracking Error
Optical Isolation, T
case
= 25ºC
Spectral Width (-20 dB)
Side Mode Suppression Ratio
Optical Return Loss
Symbol
ΔPf
ISO
SMSR
ORL
Conditions/Notes
I
MON
= const
ER = 10log(P
O
/2.0) [dB]
Double Isolator
I
op
I
op
T
case
= 25ºC
Min
-1
45
-
30
35
Typ
-
-
0.1
45
-
Max
+1
-
1.0
-
-
Unit
dB
dB
nm
dB
dB
1. Referenced to base of TO header.
Forward Path RF Characteristics
1933F Performance Parameter
Frequency Response Flatness
Response Up-tilt
1
2,3,4
2,3,4
1
Symbol
|S
21
|
Conditions/Notes
5 MHz - 1002 MHz
5 MHz - 1002 MHz
Min
-
-1
51
-
-
-
-
Typ
-
Max
1
3
Unit
dB
p-p
dB
dB
dBc
Carrier-to-Noise Ratio
CNR
Standard Linearity
Enhanced Linearity
CSO
I
op
I
op
T
case
= 25ºC
I
op
T
case
= 25ºC
-
-
-
-
-
-
-57
-60
-65
-68
Composite Second Order
Composite Triple Beat
2,3,4
Standard Linearity
Enhanced Linearity
CTB
dBc
1. I
op
, T
case
= 25C. Test with the laser Input pin matched to a 50 system.
2. 3.7% OMI, 79 NTSC unmodulated carriers (50 MHz to 550 MHz). 10 km fiber.
3. Received power = 0 dBm.
4. I
op
, T
case
= 25C. Test with the laser Input pin matched to a 75 system.
Return Path RF Characteristics
1933R Performance Parameters
Frequency Response Flatness
Second Order Distortion
Standard Linearity
Enhanced Linearity
2
2
1
Symbol
|S
21
|
Conditions/Notes
5 MHz - 200 MHz
P
F
= 3 dBm, OMI = 10% each
2-tone test: f1=7MHz, f2=56MHz
20 km of fiber
(7.5 dB total loss with connector) f1 + f2
P
F
= 3 dBm, OMI = 10% each
2-tone test: f1=7MHz, f2=56MHz
20 km of fiber
(7.5 dB total loss with connector) 2f2-f1
Min
-
Typ
-
Max
1
Unit
dB
p-p
DSO
-
-
-
-
-52
-58
dBc
Third Order Distortion
Standard Linearity
Enhanced Linearity
DTB
-
-
-
-
-63
-65
dBc
1. I
op
, T
case
= 25C. Test with the laser Input pin matched to a 50 system.
2. I
op
, T
case
= 25C. Test with laser input pin matched to a 75 system.
| REV 2012.08
Information contained herein is deemed reliable and accurate as of the issue date. EMCORE reserves the right to change the design or specification at any time without notice.
1933 F/R/W Coaxial DFB Laser Diode
1310 nm, Wide Bandwidth 5 MHz – 4000 MHz
DATASHEET | AUGUST 2012
FIBER OPTICS
Wide Bandwidth Path RF Characteristics
1933W Performance Parameters
Frequency Response Flatness
Input Third Order Intercept
1dB Compression Point
Relative Intensity Noise
(BW = 50MHz – 2GHz)
3
2
1
Symbol
|S
21
|
IIP3
P
1dB
Conditions/Notes
900 MHz – 4000 MHz
Standard Linearity, I
bb
I
bb
Tc = 25°C, Iop
Constant opt power
Tc = -20°C to +85°C, Iop
Constant opt power
Min
-
30
16
-150
-145
Typ
-
-
-
-
-
Max
4
-
-
-
-
Unit
dB
p-p
dBm
dBm
dB/Hz
dB/Hz
4
RIN
1. I
op
, T
case
= 25C. Test with the laser Input pin matched to a 50 system.
2. IIP3 is measured at I
bb
where I
bb
is the bias point at which simultaneously the laser at its best linearity and the optical
power is within specification. Test Frequency F1 = 2700MHz, F2 = 2703MHz, RF in = 0dBm/frequency. 0km fiber.
3. Test at 2700MHz. 0km fiber.
4. Guaranteed by design. Not to be tested in production
Package Outline Drawing (dimensions are in mm)
Mounting Bracket
| REV 2012.08
Information contained herein is deemed reliable and accurate as of the issue date. EMCORE reserves the right to change the design or specification at any time without notice.
1933 F/R/W Coaxial DFB Laser Diode
1310 nm, Wide Bandwidth 5 MHz – 4000 MHz
DATASHEET | AUGUST 2012
FIBER OPTICS
Reliability/Quality
Designed to meet qualification requirements of Telcordia
TM
(Bellcore) GR-468-CORE.
Schematic and Pinout
Schematic and Pinout A
3
PD
4
2
LD
1
Pin Definitions for Pinout A
Pin
1
2
3
4
Description
LD Anode, Case Ground
LD Cathode
PD Cathode
PD Anode
Pinout A
Bottom View
Laser Safety
This product meets the appropriate standard in Title 21 of the Code of Federal Regulations (CFR). FDA/CDRH Class IIIb
laser product. This device has been classified with the FDA/CDRH under accession number 0220191.
Wavelength = 1.3
m.
Maximum power = 50 mW.
Because of size constraints, laser safety labeling (including an FDA class IIIb label) is not affixed to the module, but
attached to the outside of the shipping carton. Product is not shipped with power supply.
Caution: Use of controls, adjustments and procedures other than those specified herein may result in hazardous
laser radiation exposure.
DANGER
INV IB LA RRA TIO
IS LE SE
DIA N
A O DIR CT E P SU T BE
V ID
E
X O RE O AM
W ele
av ngth: 1
.3 m
M .O
ax utpu 50 m ,
t:
W
Cla IIIb La r P
ss
se roduc
t
DANGER
INVISIBLE LASER RADIATION
IS EMITTED FROM THE END
OF FIBER OR CONNECTOR
Avoid direct exposure to beam
Do not view beam directly with
optical instruments
INVISIBLE LASER RADIATION EMITTED FROM END OF FIBER OR CONNECTOR
A oide os to b m
v
xp ure
ea
C s 3BL e P duc IE 0 5 1 3 M . O tput:50 m
la s
as r ro t C-6 82 99
ax u
W
W ve ng 1
a le th: .3 m
| REV 2012.08
Information contained herein is deemed reliable and accurate as of the issue date. EMCORE reserves the right to change the design or specification at any time without notice.
With the improvement of economic level, cars are gradually becoming people's daily means of transportation. However, the electronic products that people carry with them, such as mobile phones, cannot ...
I use a multi-byte transceiver state machine to send and receive multi-byte communication data. For example, 3a 03 22 00 02 ff ff, in hexadecimal, add 3a 03 22 to get the sum, output sum 00 02 ff ff, ...
[i=s] This post was last edited by star_66666 on 2018-3-13 13:21 [/i] [size=18px][color=#333333][font=微软雅黑]The read file was implemented before, and the write function is continued. Add the following ...
Platform: s3c2440 + wince5.0 UART1 is connected to the UART of the microcontroller on the same PCB board, 3-wire system, TTL, both powered by 3.3v. Phenomenon: (1) In CE, the serial port debugger send...
I used Altium Designer 10 and 14 to measure the line length of the same data bus on the same PCB board, and found that there was a big difference, and the difference could not be corrected. Which vers...
Analog engineers have traditionally struggled with complexity when designing power supplies that required multiple outputs, dynamic load sharing, hot-swap, or extensive fault-handling capabilities....[Details]
The reason for the light decay of white LEDs: the decline of phosphor performance
So far, the rapid decline of the luminous performance of white light LEDs, especially low-power white light LE...[Details]
We know that microcontroller development tools generally include real-time online emulators and programmers. Among them, online emulators are very good tools, but they are also more expensive...[Details]
Vertical cavity surface emitting lasers (VCSELs) are gradually replacing traditional edge emitting lasers, especially in low bandwidth and short-distance communication systems where cost factors ar...[Details]
0 Introduction
High-precision current source can provide high-precision current supply for precision instruments, and is suitable for automatic measurement tasks of various resistors in semico...[Details]
1 Load Regulation
Changes in power supply load will cause changes in power supply output. When the load increases, the output decreases, and vice versa, when the load decreases, the output inc...[Details]
Nowadays, more and more people have digital cameras. The convenience and speed of digital cameras have gradually replaced film cameras and become the main tool for people's daily photography. The n...[Details]
Direct digital frequency synthesis (DDS) has fast frequency switching and modulation capabilities and is widely used. However, when low power consumption and low cost are the main considerations, D...[Details]
0 Introduction
With the rapid development of modern power electronics technology, various power electronic devices have been widely used in various fields such as power systems, industry, an...[Details]
In recent years, the application of single-chip microcomputer systems in the field of industrial measurement and control has become more and more extensive. However, for industrial sites with harsh...[Details]
Globally, the market for airbags and other restraint systems consists of different geographical regions, each with its own characteristics and needs. North America first introduced airbags in mass-...[Details]
Various electronic and electromagnetic interference inside and outside the car often puts automotive electronic equipment in dangerous working conditions, degrading the performance of electronic eq...[Details]
Current sensing in automotive applications includes controlling the current through solenoids and injectors. For example, during diesel injection, we rapidly increase the current to the induction i...[Details]
SL11R is a 16-bit RISC microcontroller with a USB interface produced by Scanlogic. Its core processing speed reaches 48MIPS. It has rich hardware resources and 32-bit programmable I/O ports, and ca...[Details]
0 Introduction
The tobacco leaf curing process is a key step in producing high-quality tobacco leaves, and the quality of flue-cured tobacco is closely related to the temperature and humidit...[Details]
Industrial Control Electronics
京公网安备 11010802033920号
EEWORLD
