ICHAUS IC212

iC212
HIGHSPEED PHOTORECEIVER
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FEATURES
APPLICATIONS
♦
♦
♦
♦
♦
♦ Fast pulse and transient
measurement
♦ Optical triggering
♦ Optical front-end for
oscilloscopes
Bandwidth DC to 1.4 GHz
Si PIN photodiode, Ø 0.4 mm active area diameter
Spectral response range λ = 320 to 1000 nm
Amplifier transimpedance (gain) 3.125 V/mA
Max. conversion gain 1.625 V/mW @ 760 nm
BLOCK DIAGRAM
Copyright © 2010 iC-Haus
http://www.ichaus.com
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iC212
HIGHSPEED PHOTORECEIVER
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DESCRIPTION
The iC-Haus Highspeed Photoreceiver iC212 has
been developed for optical high speed measurement.
With its bandwidth ranging from DC up to 1.4 GHz
it detects photo signals from constant light to high
speed with rise times down to 280 ps. The iC212
Highspeed Photoreceiver also features offset adjustment to compensate DC levels of the input signal.
The photodiode used offers a spectral range from
320 to 1000 nm with an active area diameter of about
Ø 0.4 mm, which is increased by an Ø 1.5 mm ball
lens, resulting in an effective usable area of typical
0.75 mm². The Highspeed Photoreceiver is able to
detect optical power levels in the sub mW range at
GHz speed.
The iC212 Highspeed Photoreceiver comes with M6
mounting holes for integration in optical bench systems and an optional fiber-optic input adapter for optical fiber coupling.
ABSOLUTE MAXIMUM RATINGS
Beyond these values damage may occur; device operation is not guaranteed.
Item
No.
Symbol
Parameter
Conditions
Unit
Min.
Max.
G001 Pmax
Optical Input Power
10
mW
G002 Vs
Power Supply Voltage
±20
V
ELECTRICAL CHARACTERISTICS
Test Conditions: Vs = ±15 V, Ta = 25 °C, System Impedace 50 Ω
Item
No.
Symbol
Parameter
Conditions
Unit
Min.
Gain
101 A
Amplifier Transimpedance
Conversion Gain
50 Ω load
λ = 760 nm
Typ.
Max.
3.125
1.625
V/mA
V/mW
1.4
Ghz
±1
dB
Frequency Response
201
fmax
Upper Cut-Off Frequency
202
∆A
Gain Flatness
-3 dB
203
tr
Rise Time
10 to 90%
280
ps
204
tpd
Propagation Delay
optical in => electrical out, 50% to 50%
750
ps
0.4
mm
Detector (Si PIN photodiode)
301
d
Active Area Diameter
ball lens Ø 1.5 mm
302
Aeff
Effective Active Area
ball lens Ø 1.5 mm, note tolerances from Fig. 3
303
304
λ
Spectral Range
Pmax
Max. Optical Input Power
average
linear amplification @ 760 nm
10
615
mW
µW
305
NEP
Noise equivalent power
including amplifier noise, at λ=760nm and f =
1 GHz; (for frequency dependence see Fig. ??)
115
pW/
√
Hz
0.75
320
mm²
1000
nm
Output
401
Rout
Output Impedance
402
Vout
Output Voltage Swing
50 Ω load, for linear amplification
-0.3
50
1.0
403
Vos
Offset Voltage (adjustable)∗
DC offset cancellation
-1.25
0.15
V
404
Pos
Offset (adjustable)∗
equivalent optical power
-92
750
µW
405
twu
Warm-Up Time
stable offset voltage
Ω
30
V
min
Power Supply
501
Vs
Supply Voltage
502
Is
Supply Current
∗
The output is clipped to -0.5 V, if the offset voltage is less than 0.5 V and no DC light is present.
±15
±150
V
mA
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HIGHSPEED PHOTORECEIVER
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CONTENTS
The purchased parts package includes
• Highspeed Photoreceiver iC212
• Power adapter (230 VAC)
• Coaxial cable with SMA plugs
• SMA to BNC adapter
• Fiber adapter
Figure 1: Box contents
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DIMENSIONS
Figure 2: Case dimensions (all units in mm)
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CONNECTORS
Input
Optical, with microbench adapter
(Ø 25 mm) and SMA fiber adaption
Output
SMA Connector
Power Supply Hirose series HR10-7R-6P, 6-Pin
Pin 1, 2: +Vs
Pin 3, 6: GND
Pin 4, 5: -Vs
Table 1: Connectors
PHOTODIODE WITH BALL LENS
Figure 3: Photodiode with ball lens (lens type borosilicate glass)
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RESPONSE
Figure 4: Spectral response
Figure 5: Pulse response
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APPLICATION NOTES
These application notes are meant to demonstrate
some typical measurement tasks, carried out with the
iC212 and verified with a standard optical power meter.
Mesurement of total optical output power Popt
1. Put laser in pulse mode
2. Adjust lens, for maximum amplitude at the output
of iC212 (Fig. 6)
3. Read amplitude: U = 0.803 V (Fig. 7)
Calculation: λ = 635 nm, spectral response taken
from Figure 4: S(@635 nm) = 1.34 V/mW
Popt (iC212) =
U
0.803 V
=
= 0.60 mW
V
S
1.34 mW
Figure 7: Oscilloscope reading
4. Put laser in CW mode
5. Put Newport sensor into laser beam and read the
power: Popt (Newport) = 0.641 mW (Fig. 8)
The results match within 7%.
Figure 8: Total optical output power with 1 cm² sensor (Newport)
Figure 6: The laser light focused with a collecting
lens onto the sensor
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Measurment of Irradiance E
1. Put laser in CW mode
2. Homogenisation of laser light with microlens arrays (Fig. 10)
3. Put iC212 into the center of the homogenised
laser light (Fig. 11)
4. Read oscilloscope: U = 76 mV (Fig. 12)
Calculation: λ = 659 nm, spectral response taken
from Figure 4: S(@659 nm) = 1.42 V/mW, effective area (Item No. 302: Aeff = 0.75 mm²)
E(iC212) =
=
6. With a sensor area of 100 mm² this results in
E(Newport) = 0.0644 mW/mm²
The results match within 10%.
U
S ∗ Aeff
0.076 V
mW
= 0.071
V
mm2
1.42 mW
∗ 0.75 mm2
Figure 11: iC212 in the center of the homogenised
laser light
Figure 9: Laser 659 nm, 150 mW with two microlens arrays for homogenisation
Figure 12: Oscilloscope reading
Figure 10: Homogeneously illuminated area of ca.
4 cm x 4 cm
5. Put Newport sensor into laser beam and read the
power: Popt (Newport) = 6.441 mW (Fig. 13)
Figure 13: Newport sensor in the center of the homogenised laser light
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Measuring time of flight
Figure 14: Laser, pole filter, beam expander, beam
splitter and two iC212
Figure 16: One iC212 positioned 30 cm closer to
the beam splitter
Figure 15: No propagation time difference at same
distance from beam splitter
Figure 17: 30 cm distance difference means 1 ns
propagation time difference
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Fiber-optic input
Figure 18: Laser, SMA fiber collimator, fiber, iC212
fiber adapter, iC212
Figure 20: SMA fiber collimator
Figure 19: iC212 fiber adapter
Figure 21: Fiber transmitted light pulse
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Noise Equivalent Power (NEP)
NEP specifies the lowest light power (Pmin) that can
be detected by the sensor. In that case the signal to
noise ratio (S/N) would be 1, which means the signal
to be measured is of the same magnitude as the noise.
Pmin (λ) =
√
Smax
∗ NEP ∗ BW
S(λ)
Pmin (λ) - minimum detectable power, which can be
distinguished from noise (only white noise,
1/f-noise ignored)
S(λ) - photo sensitivity at wavelength λ
Smax - maximum photo sensitivity
NEP - NEP at maximum photo sensitivity
BW
- bandwidth
Example
Blue LED with λ = 473 nm, square wave modulated f =
1 MHz (T = 1 µs), bandwidth of measuring circuit BW =
93 MHz.
Smax
= 1.625 V/mW
√ (Figure 4)
NEP
= 115 pW/ Hz (Item No. 305)
S(λ = 473 nm) = 0.67 V/mW (Figure 4)
1.625
pW √
∗ 115 √
∗ 93 MHz
0.67
Hz
= 2.7 µWRMS
Pmin (λ = 473 nm) =
NEP(λ)
= INV(f) * 1/S(λ)
NEP(λ = 473 nm) = INV(93 MHz)
/ S(λ = 473 nm)
√
NEP(λ = 473 nm) = 215 nV/ √Hz * 1 mW / 0.67 V
= 320 pW/ Hz
√
Noise(BW)
= NEP(λ =√473 nm)
√ * BW
Noise(93 MHz) = 320 pW/ Hz * 93 MHz
= 3.09 µWRMS
As to be expected this value is slightly higher than in
the first estimation.
Mesurement of minimum optical power Pmin (λ)
1. Homogenisation of the blue LED light with microlens arrays (Figure 23)
2. LED modulation with 1 MHz
3. Change distance between iC212 and LED until signal is barely distinguishable from noise
(method imprecise but rather simple to get a basic estimation)
4. Put Newport sensor at same distance as iC212
into the LED beam and read the power: PM =
126 µW (Figure 25)
Because of the duty cycle (50%), the measured power
has to be multiplied by 2. The Newport sensor is completely illuminated (100 mm²). Hence the irradiance
can be calculated to
E(Newport) = 2 ∗
This calculation is only valid, if the input noise is frequency independent. Figure 22 shows the input noise
(INV = Input Noise Voltage) of the photo amplifier.
µW
126 µW
= 2.52
2
100 mm
mm2
With the effective area of the iC212 sensor (Item No.
302, Aeff = 0.75 mm²) this yield a total power of
µW
∗ 0.75 mm2
mm2
= 1.9 µW
Pmin (λ = 473, measured) = 2.52
This matches the calculated value reasonably well.
Output noise without signal:
Figure 22: Input Noise Voltage as a function of the
frequency - with lower frequencies there
is higher noise
√
Noise(BW ) = INV (f ) ∗ BW
√
nV
Noise(93 MHz) = 215 √
∗ 93 MHz
Hz
= 2.07 mVRMS
For frequencies
around 93 MHz an input noise of
√
215 nV/ Hz can be estimated.
A slightly higher value of µ = 3 mVRMS has been measured though.
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Figure 25: Homogeniously illuminated Newport
sensor
Figure 23: Homogenised blue LED light
Figure 26: Noise
Figure 27: Noise with signal barely detectable
Figure 24: Homogeniously illuminated iC212
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Ulbricht sphere
Figure 28: 3-port Ulbricht sphere with iC212 and
Newport power meter
Figure 30: Laser light coupled into the Ulbricht
sphere
Figure 31: Laser pulse with 260 ps rise time (channel 1)
Figure 29: HG1M laser controller with 2 W CW
laser diode
On the ideal size of an Ulbricht sphere see also "How
to select an integrating sphere for your application" by
Valerie C. Coffey at www.optoiq.com.
Figure 32: Due to size of Ulbricht sphere the pulse
gets distorted (ca. 4 ns rise time)
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Equipment used
Mesuring instruments
Tektronix:
TDS7404B, 4 GHz, 20 GS/s,
4-Channel Digital Phosphor Oscilloscope
Newport:
Optical Power Meter Model 840
Newport:
Sensor 818-ST, Sensor 818-UV,
Sensor 818-ST/CM
Newport:
819D-SL-3.3, 3-Port 3.3" Spectralon
Ulbricht Sphere
Ocean Optics: USB2000 Fiber-optic Spectrometer
320 - 1100 nm
Omicron:
LDM639.40.500, 40 mW Laser,
fMOD > 500 MHz
Femto:
HSA-X-S-1G4-SI, Ultra High Speed
Photoreceiver
iC-Haus:
iC212 Highspeed Photoreceiver,
DC to 1.4 GHz
HP:
8590L, Spectrum Analyzer
Accessories
iC-Haus: iC149, 8-Bit pulse generator ,1 to 64 ns,
compatibel to LDMxxx series lasers by Omicron
iC-Haus: iC213, 12-Bit Oszillator, 40 kHz to 500 MHz,
compatibel to LDMxxx series lasers by Omicron
iC-Haus: iC215_6, pulse width modulator,
640 ps to 10.23 ns, compatibel to LDMxxx
series lasers by Omicron and iC213
iC-Haus: HG1M, control module for high speed, high
power laser diodes
iC-Haus expressly reserves the right to change its products and/or specifications. An Infoletter gives details as to any amendments and additions made to the
relevant current specifications on our internet website www.ichaus.de/infoletter; this letter is generated automatically and shall be sent to registered users by
email.
Copying – even as an excerpt – is only permitted with iC-Haus approval in writing and precise reference to source.
iC-Haus does not warrant the accuracy, completeness or timeliness of the specification on this site and does not assume liability for any errors or omissions
in the materials. The data specified is intended solely for the purpose of product description. No representations or warranties, either express or implied, of
merchantability, fitness for a particular purpose or of any other nature are made hereunder with respect to information/specification or the products to which
information refers and no guarantee with respect to compliance to the intended use is given. In particular, this also applies to the stated possible applications or
areas of applications of the product.
iC-Haus conveys no patent, copyright, mask work right or other trade mark right to this product. iC-Haus assumes no liability for any patent and/or other trade
mark rights of a third party resulting from processing or handling of the product and/or any other use of the product.
As a general rule our developments, IPs, principle circuitry and range of Integrated Circuits are suitable and specifically designed for appropriate use in technical
applications, such as in devices, systems and any kind of technical equipment, in so far as they do not infringe existing patent rights. In principle the range of
use is limitless in a technical sense and refers to the products listed in the inventory of goods compiled for the 2008 and following export trade statistics issued
annually by the Bureau of Statistics in Wiesbaden, for example, or to any product in the product catalogue published for the 2007 and following exhibitions in
Hanover (Hannover-Messe).
We understand suitable application of our published designs to be state-of-the-art technology which can no longer be classed as inventive under the stipulations
of patent law. Our explicit application notes are to be treated only as mere examples of the many possible and extremely advantageous uses our products can
be put to.
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ORDERING INFORMATION
Type
Package
iC212
Order Designation
iC212
For technical support, information about prices and terms of delivery please contact:
iC-Haus GmbH
Am Kuemmerling 18
D-55294 Bodenheim
GERMANY
Tel.: +49 (61 35) 92 92-0
Fax: +49 (61 35) 92 92-192
Web: http://www.ichaus.com
E-Mail: [email protected]
Appointed local distributors: http://www.ichaus.com/sales_partners