Sensortechnics AD500-9-400M-TO5 0.500 mm active area Datasheet

First Sensor APD Hybrid Series Data Sheet
Part Description AD500-9-400M-TO5
US Order # 05-051-01, # 05-051-02
International Order # 50049001, # 50049002
PIN 5
CASE/ GND
2.2
PIN 1
Vout+
Ø 0.46
5 PL
Ø9.2
Ø6.60
113°
VIEWING
Ø8.3
ANGLE
PIN 2
VCC
PIN 4
Ø5.08
PIN CIRCLE
Vout-
4.2
±1
PIN 3
7.6 MIN
5 PL
1.00 SQ
+VBIAS
BACKSIDE VIEW
ACTIVE AREA: 0.196 mm 2
(500 µm DIAMETER)
CHIP DIMENSIONS
APPLICATIONS
• Lidar
• Analytical instruments
• Medical equipment
ABSOLUTE MAXIMUM RATING
SYMBOL PARAMETER
MIN
TSTG
TOP
Storage Temp
Operating Temp
Soldering Temp
Power Dissipation
Single Supply Voltage
Supply Current
TSOLDERING
P
Vcc
Icc
-55
0
+3.0
-
SCHEMATIC
VCC (+5V)
PIN 2
C1
SPECTRAL RESPONSE at M = 100
MAX
UNITS
+125
+60
+240
360
+5.5
63
°C
°C
°C
mW
V
mA
70
OUT+
PIN 1
60
50
40
30
20
10
0
400
500
600
OUTPIN 4
AD500-9
700
800
900
1000
1100
WAVELENGTH (nm)
PIN 5
CASE/GND
C2
C
S
Ro
∅ 0.500 mm active area
Low noise
High gain
Long term stability
RESPONSIVITY (A/W)
•
•
•
•
PLI A NT
OM
DESCRIPTION
The AD500-9-400M-TO5 is an Avalanche Photodiode Amplifier
Hybrid containing a 0.196 mm2 active area APD chip integrated
with an internal transimpedance amplifier. Hermetically
packaged in a TO-5 with a borosilicate glass window cap.
H
FEATURES
PIN 3
+V BIAS
ELECTRO-OPTICAL CHARACTERISTICS @ 23°° C (VCC = single supply +3.3V, RL = 100W unless otherwise specified)
SYMBOL
CHARACTERISTIC
TEST CONDITIONS
MIN
TYP
MAX UNITS
ƒ-3dB
S
Icc
Frequency Response
Sensitivity*
Supply Current
-3dB @ 905 nm
λ = 905 nm; M = 100
Dark state
-------
400
145
34
----63
MHz
mV/µW
mA
* Sensitivity = APD responsivity (0.58 A/W X 100 gain) x TIA gain (2.5K)
Use US order number 05-051-01, or International order number 50049001 for breakdown voltage range of 160-200 Volts.
Use US order number 05-051-02, or International order number 50049002 for breakdown voltage range of 200-240 Volts.
These devices are sensitive to electrostatic discharge. Please use ESD precautions when handling.
Disclaimer: Due to our policy of continued development, specifications are subject to change without notice.
11/6/2013
AVALANCHE PHOTODIODE DATA @ 23 °C
SYMBOL
CHARACTERISTIC
TEST CONDITIONS
MIN
TYP
MAX
UNITS
ID
C
VBR
Dark Current
M = 100 (see note 2)
--0.8
5.0
nA
Capacitance
M = 100 (see note 2)
--1.2
--pF
Breakdown Voltage (see note 1)
ID = 2 µA
160
--240
V
Temperature Coefficient of VBR
1.25
--1.55
V/K
52
60
58
A/W
Responsivity
M = 100; = 0 V; λ = 905 nm
Bandwidth
-3dB
--0.5
--GHz
∆ƒ3dB
Rise Time
M = 100
--0.55
--ns
tr
Optimum Gain
50
60
------“Excess Noise” factor
M = 100
2.5
----“Excess Noise” index
M = 100
0.2
----Noise Current
M = 100
1.0
pA/Hz1/2
--Max Gain
200
--1/2
----NEP
Noise Equivalent Power
2.0 X 10-14
M = 100; λ = 905 nm
W/Hz
Note 1: The following different breakdown voltage ranges are available: (160 – 200 V), (200 – 240 V).
Note 2: Measurement conditions: Setup of photo current 1 nA at M = 1 and irradiated by a 880 nm, 80 nm bandwidth LED. Increase the photo
current up to 100 nA, (M = 100) by internal multiplication due to an increasing bias voltage.
TRANSIMPEDANCE AMPLIFIER DATA @ 25 °C
(Vcc = +3.0 V to 5.5 V, TA = 0°C to 70°C, 100Ω load between OUT+ and OUT-. Typical values are at TA = 25°C, Vcc = +3.3 V)
PARAMETER
MIN
TYP
MAX
Supply Voltage
TEST CONDITIONS
3
5
5.5
UNITS
V
Supply Current
--2.10
48
220
2
1
-----
34
63
3.40
52
575
----668
-----------
mA
Transimpedance
Differential, measured with 40 µA p-p signal
2.75
kΩ
Output impedance
Single ended per side
50
Ω
Maximum Differential Output Voltage
380
mV p-p
Input = 2 mA p-p with 100 Ω differential termination
AC Input Overload
--mA p-p
DC Input Overload
--mA
Input Referred RMS Noise
TO-5 package, see note 4
490
nA
Input Referred Noise Density
See note 4
11
pA/Hz1/2
Small signal bandwidth
Source capacitance = 0.85 pF, see note 3
1.525
2.00
GHz
--Low Frequency Cutoff
-3 dB, input < 20 µA DC
30
kHz
Transimpedance Linear Range
Peak to peak 0.95 < linearity < 1.05
40
--µA p-p
Power Supply Rejection Ratio
Output referred, f < 2 MHz, PSSR = -20 Log (∆Vout /
--50
dB
(PSRR)
∆Vcc)
Note 3: Source capacitance for AD500-9-400M-TO5 is the capacitance of APD.
Note 4: Input referred noise is calculated as RMS output noise/ (gain at f = 10 Mhz). Noise density is (input referred noise)/√bandwidth.
TRANSFER CHARACTERISTICS
The circuit used is an avalanche photodiode directly coupled to a high speed data handling transimpedance amplifier. The output of the APD
(light generated current) is applied to the input of the amplifier. The amplifier output is in the form of a differential voltage pulsed signal.
The APD responsivity curve is provided in Fig. 2. The term Amps/Watt involves the area of the APD and can be expressed as
Amps/mm2/Watts/mm2, where the numerator applies to the current generated divided by the area of the detector, the denominator refers to the
power of the radiant energy present per unit area. As an example assume a radiant input of 1 microwatt at 905 nm. The APD’s corresponding
responsivity is 0.58 A/W.
If energy in = 1 µW, then the current from the APD = (0.58 A/W) x (1x10-6W) = 0.58 µA. We can then factor in the typical gain of the APD
of 100, making the input current to the amplifier 58 µA. From Fig. 5 we can see the amplifier output will be approximately 100 mV p-p.
APPLICATION NOTES
The AD500-9-400M-TO5 is a high speed optical data receiver. It incorporates an internal transimpedance amplifier with an avalanche
photodiode.
This detector requires +3.5 V to +5.0 V voltage supply for the amplifier and a high voltage supply (100-240 V) for the APD. The internal APD
follows the gain curve published for the AD500-9-TO52-S1 avalanche photodiode. The transimpedance amplifier provides differential output
signals in the range of 200 millivolts differential.
In order to achieve highest gain, the avalanche photodiode needs a positive bias voltage (Fig. 1). However, a current limiting resistor must be
placed in series with the photodiode bias voltage to limit the current into the transimpedance amplifier. Failure to limit this current may
result in permanent failure of the device. The suggested initial value for this limiting resistor is 390 KOhm.
When using this receiver, good high frequency placement and routing techniques should be followed in order to achieve maximum frequency
response. This includes the use of bypass capacitors, short leads and careful attention to impedance matching. The large gain bandwidth
values of this device also demand that good shielding practices be used to avoid parasitic oscillations and reduce output noise.
11/6/2013
Fig. 1: APD GAIN vs BIAS VOLTAGE
Fig. 2: APD SPECTRAL RESPONSE (M = 1)
0.7
1000
0.6
0.5
GAIN
A/W
100
0.4
0.3
10
0.2
0.1
1
140
150
160
170
180
190
200
210
0.0
400
220
500
APPLIED VOLTAGE (V)
Fig. 3 : AMPLIFIER OUTPUT vs TEMPERATURE
600
700
800
900
WAVELENGTH (nm)
1000
1100
Fig.4 : APD CAPACITANCE vs BIAS VOLTAGE
380
35
360
30
CAPACITANCE (pF)
AMPLITUDE (mV)
400
340
320
300
280
260
25
20
15
10
240
5
220
0
200
0
0
20
40
60
10
20
30
40
50
60
70
80
REVERSE BIAS (V)
80
AMBIENT TEMPERATURE (°C)
Fig. 6: TOTAL FREQUENCY RESPONSE
200
150
TRANSIMPEDANCE (db)
DIFFERENTIAL OUTPUT VOLTAGE (mV p-p)
Fig. 5: AMPLIFIER TRANSFER FUNCTION
100
50
0
-50
-100
-150
-200
-100
-75
-50
-25
0
25
50
INPUT CURRENT (µ A)
75
100
70
65
60
55
50
1M
10M
100M
400M
1G
FREQUENCY (Hz)
USA:
International sales:
First Sensor, Inc.
5700 Corsa Avenue, #105
Westlake Village, CA 91362 USA
T + 818 706-3400
F + 818 889-7053
[email protected]
www.first-sensor.com
11/6/2013
First Sensor AG
Peter-Behrens-Str. 15
12459 Berlin, Germany
T + 49 30 6399 2399
F + 49 30 639923-752
[email protected]
www.first-sensor.com