DATASHEET
Photon Detection
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
Excelitas’ LLAM-1550E InGaAs APD Preamplifier Modules exhibit enhanced damage threshold and greater resilience
when exposed to higher optical power densities.
Key Features
• System bandwidth of 50 MHz and 200MHz
• Ultra low noise equivalent power (NEP)
• Spectral response range:
• Si APD: 400 to 1100 nm
• InGaAs APD: 1100 to 1700 nm
• Typical power consumption: 150 mW (without
TEC powered on)
• ±5 V amplifier operating voltages
• 50 Ω AC load capability (AC-Coupled)
• Hermetically-sealed TO-66 flange package for
additional heat sinking
• High reliability
• Light entry angle, over 130°
• Model 1060E and 1550E exhibits enhanced
damage threshold
• RoHS-compliant
• Available in both COTS and custom variations
Applications
• LIDAR
• Range finding
• Laser designation
• Confocal microscopy
• High-speed, extreme low-light detection
• Distributed temperature sensing (DTS)
• Analytical instrumentation
• High-speed, free-space optical communication
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LLAM Series-Rev.2-2022.01 Page 1 of 11
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
Table 1. Performance Specifications – LLAM 900/1060(E) Models (900 nm and YAG-enhanced Si APD)
Test conditions: Case temperature = 22˚C, Vamp = ±5 V, HV = Vop (see Note 1), RL = 50 Ω AC coupled and TEC off
LLAM-900-R5BH
Detector Type
Parameter
Photosensitive Area
Active diameter
Active area
Field of View
Nominal field of view α (see Figure 8)
Nominal field of view α’ (see Figure 8)
System bandwidth, f-3dB
Temperature coefficient of Vop for constant gain
Vop for specified responsivity
Responsivity
at 830 nm
at 900 nm
at 1064 nm
Rf (Internal feedback resistor)
Noise equivalent power (NEP) (Note 2)
Average from 100 kHz to f-3dB, ∆f = 1.0 Hz
at 830 nm
at 900 nm
at 1064 nm
Output spectral noise voltage
Averaged from 100 kHz to f-3dB
Output impedance
Rise time, tr ( = 830, 900 and 1064 nm)
10% to 90% points
Fall time, tf ( = 830, 900 and 1064 nm)
90% to 10% points
Recovery time after overload (Note 3)
Output voltage swing (1 kΩ load) (Note 4)
Output voltage swing (50 Ω load) (Note 4)
DC output offset voltage
APD temperature (case at room temperature)
Thermistor value (Note 5)
Positive supply current (V+)
Negative supply current (V-)
Min
175
180
LLAM-1060-R8BH
LLAM-1060E-R8BH
(C30954EH APD)
Min
Typical
Max
Units
0.5
0.2
0.8
0.5
mm
mm²
139
142
200
0.7
Note 1
138
143
200
2.2
Note 1
Degrees
(C30902EH APD)
Typical
Max
175
260
275
460
400
325
370
200
8.2
12
33
435
kV/W
kV/W
kV/W
kΩ
35
40
55
65
30
25
50
90
80
150
fW/Hz
fW/Hz
fW/Hz
15
40
25
50
10
40
30
50
nV/Hz
Ω
33
2
2
ns
2
2
ns
150
2
0.7
-1
-10
MHz
V/˚C
V
3
0.9
0.25
5.1±5%
20
10
1
85
35
20
150
2
0.7
-1
-10
3
0.9
0.25
1
85
5.1±5%
20
10
35
20
ns
Vpp
Vpp
VDC
⁰C
kΩ
mA
mA
Note 1: A specific value of Vop within the specified range will be supplied with each device.
Note 2: NEP is calculated as the output spectral noise voltage divided by the typical responsivity.
Note 3: 0 dBm with 250ns pulses.
Note 4: Pulsed operation, AC-coupled
Note 5: The temperature of the thermistor in Kelvin can be calculated using the following equation:
β
T[K] = ln(𝑅/𝑟 ),where R is the measured thermistor resistance in Ω, 𝛽 = 3200, R 0 = 5100 Ω, T0 = 298.15 𝐾 and
−
r∞ = R 0 e
β
T0
∞
≅ 0.1113.
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Page 2 of 10
LLAM Series-Rev.2-2022.01
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
Table 2. Performance Specifications − LLAM-1550(E) Models (1550 nm peak response InGaAs APD)
Test conditions: Case temperature = 22˚C, Vamp = ±5 V, HV = Vop (see Note 1), RL = 50 Ω AC coupled and TEC off
Detector type
Parameter
Photosensitive Area
Active diameter
Active area
Field of View
Nominal field of view α (see Figure 8)
Nominal field of view α’ (see Figure 8)
System bandwidth, f-3dB
Temperature coefficient of Vop for constant gain
Vop for specified responsivity
Responsivity
at 1300 nm
at 1550 nm
Rf (Internal feedback resistor)
Noise equivalent power (NEP) (Note 2)
Average from 100 kHz to f-3dB, ∆f = 1.0 Hz
at 1300 nm
at 1550 nm
Output spectral noise voltage
Averaged from 100 kHz to f-3dB
Output impedance
Rise time, tr ( = 1300 and 1550 nm)
10% to 90% points
Fall time, tf ( = 1300 and 1550 nm)
90% to 10% points
Recovery time after overload (Note 3)
Output voltage swing (1 kΩ load) (Note 4)
Output voltage swing (50 Ω load) (Note 4)
DC output offset voltage
APD temperature (case at room temperature)
Thermistor value (Note 5)
Positive supply current (V+)
Negative supply current (V-)
LLAM-1550-R2AH
LLAM-1550E-R2AH
(C30662EH APD)
Min
Typical
Max
LLAM-1550-R08BH
LLAM-1550E-R08BH
(C30645EH APD)
Min
Typical
Max
Units
0.2
0.03
0.08
0.005
mm
mm²
140
141
50
0.2
Note 1
140
141
175
0.2
Note 1
Degrees
40
40
150
70
40
300
340
68
33
70
80
90
12
kV/W
kV/W
kΩ
150
130
180
160
250
220
375
330
fW/Hz
fW/Hz
45
40
55
50
20
40
30
50
nV/Hz
Ω
33
7
2
ns
7
2
ns
150
2
0.7
-1
-10
MHz
V/˚C
V
3
0.9
0.25
5.1±5%
20
10
1
85
35
20
150
2
0.7
-1
-10
3
0.9
0.25
1
85
5.1±5%
20
10
35
20
ns
Vpp
Vpp
VDC
⁰C
kΩ
mA
mA
Note 1: A specific value of Vop within the specified range will be supplied with each device.
Note 2: NEP is calculated as the output spectral noise voltage divided by the typical responsivity.
Note 3: 0 dBm with 250ns pulses.
Note 4: Pulsed operation, AC-coupled
Note 5: The temperature of the thermistor in Kelvin can be calculated using the following equation:
β
T[K] = ln(𝑅/𝑟 ),where R is the measured thermistor resistance in Ω, 𝛽 = 3200, R 0 = 5100 Ω, T0 = 298.15 𝐾 and
−
r∞ = R 0 e
β
T0
∞
≅ 0.1113.
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Page 3 of 10
LLAM Series-Rev.2-2022.01
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
Table 3. Absolute – Maximum Ratings, Limiting Values
Detector type
Parameter
LLAM-1060(E)-R8BH
LLAM-900-R5BH
(C30954EH)
Min
Max
(C30902EH)
Min
Max
LLAM-1550(E) Models
(C30645EH)
(C30662EH)
Min
Max
600
300
350
210
100
50
V
V
0.1
50
0.1
50
2
mW
mW
kW/cm²
85
70
±5.5
˚C
˚C
V
0.9
0.8
1.8
W
V
A
Photodiode HV bias voltage (Note 1)
at TA = +70˚C
at TA = -40˚C
Incident radiant flux, ΦM, (Note 2)
average (Note 3)
peak (Note 4)
peak (Note 5)
Case temperature
storage, Tstg
operating, TA
Preamplifier bias voltage
Thermo-Electric Cooler (TEC)
Qmax, heat-pumping capacity
Vmax, rated at 27⁰C
Imax, rated at 27⁰C
4 (for-1550)
1000 (for -1550E)
-50
-40
±4.5
85
70
±5.5
0.9
0.8
1.8
-50
-40
±4.5
85
70
±5.5
0.9
0.8
1.8
-50
-40
±4.5
Units
Note 1: The operating voltage (Vop) must remain below the breakdown voltage (Vbr), these values are worst-case
estimates. HV voltage current should be limited externally to less than 1mA.
Note 2: As demonstrated in laboratory conditions.
Note 3: Based on 0.5 W electrical power on the high voltage (HV) supply.
Note 4: Test with 30 ns pulse width.
Note 5: Tested at 1060 nm, 10 ns pulse width and 1 kHz pulse repetition rate
Figure 1. Schematic Block Diagram – LLAM Series
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Page 4 of 10
LLAM Series-Rev.2-2022.01
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
Responsivity [kV/W]
Figure 2. Typical Spectral Responsivity
500
450
400
350
300
250
200
150
100
50
0
LLAM-900-R5BH
LLAM-1060/1060E-R8BH
LLAM-1550/1550E-R2AH
400
500
600
700
800
900
1000
1100
1200
1300
1400
1500
1600
1700
1800
Wavelength [nm]
100
LLAM-1550/1550E-R08BH
Responsivity [kV/W]
90
80
70
60
50
40
30
20
10
0
800
900
1000
1100
1200
1300
1400
1500
1600
1700
1800
Wavelength [nm]
Figure 3. Typical Responsivity as a Function of Operating Voltage – LLAM-(900/1060) Series
10000
LLAM-900-R5BH
Responsivity [kV/W]
LLAM-1060/1060E-R8BH
1000
100
10
100
150
200
250
300
350
400
Operating Voltage [V]
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Page 5 of 10
LLAM Series-Rev.2-2022.01
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
Figure 4. Typical Responsivity as a function of Operating Voltage – LLAM-(1550/1550E) Series
10000
LLAM-1550/1550E-R2AH
Responsivity [kV/W]
LLAM-1550/1550E-R08BH
1000
100
10
10
15
20
25
30
35
40
45
50
55
Operating Voltage [V]
Figure 5. Typical Noise and Frequency response curves
1
Normalized frequency response [dB]
Normalized output noise voltage
1.4
1.2
1
0.8
0.6
0.4
50 MHz
200 MHz
0.2
0
0
-1
-2
-3
-4
-5
50 MHz
-6
200 MHz
-7
-8
1
10
100
1000
1
10
Frequency [MHz]
100
1000
Frequency [MHz]
Output voltage noise normalization is calculated using the following formula:
f −3 dB
Vnnormalize =
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Vn
Vnaverage
V
, where Vnaverage
=
Hz
Page 6 of 10
V
n
100kHz
2
df
f −3dB
LLAM Series-Rev.2-2022.01
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
Figure 6. Typical variation of responsivity as a function of temperature
LLAM-900-R5BH responsivity at 900 nm
100
100
-20 C
0C
23 C
45 C
10
150
175
200
Vop (V)
225
250
150
LLAM-1550/1550E-R08BH responsivity at 1550 nm
100
-20 C
0C
23 C
45 C
10
25
30
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35
40
45
Vop (V)
50
55
200
250
300
Vop (V)
350
Page 7 of 10
450
100
-20 C
0C
23 C
45 C
10
60
400
LLAM-1550/1550E-R2AH responsivity at 1550 nm
1000
Responsivity (kV/W)
1000
LLAM-1060/1060E-R8BH responsivity at 1060 nm
-20 C
0C
23 C
45 C
10
Responsivity (kV/W)
1000
Responsivity (kV/W)
Responsivity (kV/W)
1000
25
30
35
40
45
Vop (V)
50
55
60
LLAM Series-Rev.2-2022.01
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
Figure 7. Mechanical Characteristics – LLAM Series − reference dimensions shown in mm [inches]
Figure 8. Approximate field of view – LLAM Series
For incident radiation at angles ≤ 𝛼/2, the photosensitive surface is totally illuminated.
For incident radiation at angles > 𝛼/2, but ≤ 𝛼 ′ /2, the photosensitive surface is partially illuminated.
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Page 8 of 10
LLAM Series-Rev.2-2022.01
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
Table 4. Ordering Guide
Model
Nominal
Bandwidth
Wavelength
Response
900 nm (peak)
Detector
Type
C30902EH
200 MHz
1064 nm
(optimized)
C30954EH
LLAM-900-R5BH
LLAM-1060-R8BH
LLAM-1060E-R8BH
Detector
Material
Active
Diameter
0.5 mm
Comments
Silicon
0.8 mm
Enhanced damage threshold
LLAM-1550-R2AH
50 MHz
C30662EH
0.2 mm
LLAM-1550E-R2AH
Enhanced damage threshold
1550 nm (peak)
InGaAs
LLAM-1500-R08BH
175 MHz
C30645EH
LLAM-1550E-R08BH
0.08 mm
Enhanced damage threshold
Information
Excelitas Technologies’ LLAM series of Silicon and InGaAs avalanche photodiodes (APD) receiver modules feature an APD,
thermoelectric cooler (TEC) and a hybrid, all in the same hermetically-sealed modified 12-lead TO-66 flange package for increased
heat sinking. The use of a TEC eases the burden on the APD bias control to insure constant responsivity over a 5⁰C to 40⁰C ambient
temperature range.
The LLAM series modules are specifically designed for the detection of high-speed, low-light analog signals. The Si APDs used in
these devices are the same as used in Excelitas’ C30902EH and C30954EH products, while the InGaAs APDs are used in the
C30645EH and C30662EH products. These detectors provide very good response between 830 and 1550 nm and very fast rise- and
fall-times at all wavelengths. Just like the C30659 series, the preamplifier section of the LLAM module uses a very low noise GaAs
FET front end designed to operate at higher transimpedance than Excelitas’ regular C30950 Series.
The LLAM is an inverting amplifier design with an emitter follower used as an output buffer stage. To obtain the wideband
characteristics, the output of these devices should be capacitively- or AC-coupled to a 50 Ω termination. The module must not be
DC-coupled to loads of less than 2 kΩ. For field use, it is recommended that a temperature-compensated HV supply be employed
to maintain a constant responsivity over temperature.
Excelitas’ InGaAs LLAM-1060E and -1550E Preamplifier Modules, are designed to exhibit higher damage thresholds, thus providing
greater resilience when exposed to high optical power densities.
The LLAM series modules are offered as standard, RoHS-compliant, commercial off-the-shelf (COTS) products. Excelitas offers
customized modules tailored for your specific needs; modifications include bandwidth and gain optimization, use of different
APDs, FC-connectorized packaging.
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Page 9 of 10
LLAM Series-Rev.2-2022.01
LLAM Series – 900/1060/1060E/1550/1550E
Si and InGaAs Low-Light Analog APD Receiver Modules (LLAM)
RoHS Compliance
The LLAM Series of APD Preamplifier Modules are designed and built to be fully compliant with the European Union Directive
2011/65/EU – Restriction of the use of certain Hazardous Substances (RoHS) in Electrical and Electronic equipment.
About Excelitas Technologies
Excelitas Technologies is a global technology leader focused on delivering innovative, customized solutions to meet the lighting,
detection and other high-performance technology needs of OEM customers.
Excelitas has a long and rich history of serving our OEM customer base with optoelectronic sensors and modules for more than 45
years beginning with PerkinElmer, EG&G, and RCA. The constant throughout has been our innovation and commitment to
delivering the highest quality solutions to our customers worldwide.
From aerospace and defense to analytical instrumentation, clinical diagnostics, medical, industrial, and safety and security
applications, Excelitas Technologies is committed to enabling our customers' success in their specialty end-markets.
Excelitas Technologies
22001 Dumberry Road
Vaudreuil-Dorion, Quebec
Canada J7V 8P7
Telephone: (+1) 450.424.3300
Toll-free: (+1) 800.775.6786
Fax: (+1) 450.424.3345
detection.na@excelitas.com
Excelitas Technologies
GmbH & Co. KG
Wenzel-Jaksch-Str. 31
D-65199 Wiesbaden
Germany
Telephone: (+49) 611 492 430
Fax: (+49) 611 492 165
detection.europe@excelitas.com
Excelitas Technologies
International Sales Office
Bat HTDS BP 246, 91882
Massy Cedex, France
Telephone: +33 (1) 6486 2824
europedefense@excelitas.com
Excelitas Technologies
Singapore, Pte. Ltd.
8 Tractor Road
Singapore 627969
Telephone: (+65) 6775 2022
(Main number)
Telephone: (+65) 6770 4366
(Customer Service)
Fax: (+65) 6778-1752
detection.asia@excelitas.com
For a complete listing of our global offices, visit www.excelitas.com/locations
© 2013 Excelitas Technologies Corp. All rights reserved. The Excelitas logo and design are registered trademarks of Excelitas Technologies Corp. All other trademarks not owned by Excelitas Technologies or its subsidiaries that are depicted herein are the
property of their respective owners. Excelitas reserves the right to change this document at any time without notice and disclaims liability for editorial, pictorial or typographical errors.
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Page 10 of 10
LLAM Series-Rev.2-2022.01