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TRANSCRIPT
I NSTITUT DE M ICROTECHNIQUE
UNIVERSITÉ DE NEUCHÂTEL
Rue A.-L. Breguet 2 Phone: +41 32 718 3211CH-2000 Neuchâtel, Switzerland Fax: +41 32 718 3201http://www-optics.unine.ch
Design of the Phase Meterof the PRIMA Metrology System
VLT-TRE-IMT-15734-3002, Issue 3, 28/8/2003
O. Scherler, Y. Salvadé, M. Groccia and R. Dändliker
Contents
1 Introduction 2
2 Applicable documents 2
3 Acronyms 2
4 Principle 3
4.1 Photodetectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
4.2 Superheterodyne modules . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
4.3 Phasemeter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
4.4 Phase error compensation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6
5 Design of the photodetectors 6
6 Design of the superheterodyne module 7
6.1 Preamplifiers and filters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
6.2 Limiting amplifiers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
6.3 Mixers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9
7 Design of the digital phasemeter 11
7.1 Phase-locked loop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
7.2 Phase shifter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
7.3 Digital zero-crossing phasemeter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12
7.4 Phase adder . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
7.5 Error compensation fringe counter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13
7.6 Status registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
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7.7 Data transfer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
8 Design summary 15
9 Experimental tests 19
9.1 Electrical tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
9.2 Dynamic tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
9.3 Tests of accuracy . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
9.4 Tests by comparison with a HP interferometer . . . . . . . . . . . . . . . . . . . . . . . 20
9.5 Tests with long delay lines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 21
1 Introduction
In the framework of the project “Absolute interferometry for stellar interferometers” supported by theswiss national funds FINES, we are currently developing an “Optical Phase Detection Unit” (OPDU) forthe PRIMA facility of the Very Large Telescope Interferometer. The concept of this OPDU has alreadybeen established during a rider study on the PRIMA metrology supported by ESO [AD1] and a prototypeversion has been built. In this report, we propose a more detailed design of the final version of the OPDUand we present some experimental tests in order to verify its performance.
2 Applicable documents
[AD1] Prima Metrology Rider Study, VLT-TRE-IMT-15700-0001, 7/3/00.[AD2] Technical Specification for the PRIMA Metrology System, VLT-SPE-ESO-15730-2211, Is-
sue 1.0, 16/10/00.[AD3] Optical Phase Detector Unit for the PRIMA Metrology System, Design Review, VLT-TRE-
IMT-15734-0002, 20/11/00.[AD4] Technical Specification for the Design of the Phase Meter of the PRIMA Metrology System,
VLT-SPE-ESO-15734-2921, Issue 1.0, 5/12/02.
3 Acronyms
EOB End Of Block
EOT End Of Text
LCU Local Control Unit
NEP Noise Equivalent Power
OPD Optical Path Difference
OPDU Optical Phase Detection Unit
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PLD Programmable Logic Device
PLL Phase-Locked Loop
SNR Signal to Noise Ratio
SOB Start Of Block
SOT Start Of Text
TIM Time Interface Module
VCO Voltage Controlled Oscillator
4 Principle
The setup of Fig. 1 is composed of two heterodyne interferometers, one for the reference object, with aheterodyne frequency of 650 kHz and the other for the science object, with a heterodyne frequency of450 kHz. A Nd:YAG laser emitting at 1319 nm will be used for both interferometers. The wavelength of1319 nm was chosen to avoid straylight affecting the wavefront curvature sensor of the adaptive opticssystem that works in the visible spectrum.
In the phasemeter prototype, a frequency offset of 80 MHz was generated between both interferometersto avoid crosstalk. The heterodyne frequencies were generated using acousto-optic modulators workingat +40 and+39.35MHz for the reference interferometer and at−40 and−39.55MHz for the scienceinterferometer. However, it was discovered that the acousto-optic modulators suffer from acoustic backreflections in the crystal. As a result, the device optimized for+40MHz frequency shift also exhibits asmall amount of optical power which is down shifted by 40MHz. This behaviour led to parasitic super-heterodyne signals at 200 kHz that affected the phase resolution. Therefore, for the remaining of the tests,the operating frequency of the acousto-optic modulators generating the 650 kHz signal were changed to38 and 38.65 MHz. The frequency offset between both interferometers is therefore of 78 MHz. Table 1lists the frequencies used in the final version of the phasemeter.
Channel A (science) Channel B (ref)
ν+38MHz ν+38.65MHz ν−39.55MHz ν−40MHz
f1 = 650kHz f2 = 450kHz
ν = 3×108/1319×10−9Hz
∆ν = 78MHz
f1− f2 = 200kHz
Table 1: Heterodyne frequencies for reference and science interferometers.
After AC coupling, the two detected interference signals are of the form
Imeas,1 = I1cos(2πf1t+ϕ1) and Imeas,2 = I2cos(2πf2t+ϕ2) (1)
with
ϕ1 =4πν
cL1 and ϕ2 =
4π(ν+∆ν)c
L2 (2)
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DL DD
LI 2
Tele
scop
e 1
Tele
scop
e 2
Freq
uenc
y sh
ifter
m
odul
e
Seco
ndar
y FS
U
LASE
RFr
eque
ncy
shift
er
mod
ule
I 1
Ref
eren
ce o
bjec
t
Scie
nce
obje
ct
PRIM
ARY
FSU
Ret
rore
flect
or o
n M
2
Figure 1: Principle of detection.
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where L1, L2 are the path difference for the science and reference interferometers, respectively.
The optical phase detection unit (OPDU) is shown in Fig. 2. It consists of four photodetectors, twosuperheterodyne modules and a digital phasemeter.
450 kHzSuperheterodyne module Phasemeter,
Phase errorcompensation
Photodetectors
Superheterodyne module
200 kHz
200 kHz
Mixer
Mixer
Imeas,1
650 kHz
Imeas,2
450 kHz
Iref,1
650 kHz
Iref,2
Limiter
Limiter
Limiter
Limiter
Limiter
Limiter
DigitalPhasemeter
ErrorcompensationFringe counter
Figure 2: Optical phase detection unit.
4.1 Photodetectors
The four InGaAs photodetectors measure the two probe signals Imeas,1 and Imeas,2 for the science andreference interferometers respectively, and their corresponding reference signals Iref,1 and Iref,2. Weshowed in [AD1] that the minimal optical power which is required to achieve the desired resolution islimited by the electronic noise (amplifier noise + thermal noise). Therefore, the photodetectors shouldbe designed to achieve the best signal-to-noise ratio (SNR).
4.2 Superheterodyne modules
The superheterodyne module allows to access directly the difference of the interferometric phasesϕ1−ϕ2
which is mainly sensitive to the differential optical path difference∆L = L1− L2. Indeed, by mixingelectronically the two interference signals and by band-pass filtering around f1− f2, we obtain a signal
Imeas(t) = I12cos[2π(f1− f2)t+ϕ1−ϕ2] . (3)
Similarly, a reference signal of frequency f1− f2 is generated from the two individual reference signals re-lated to each interferometer by means of the second superheterodyne module. Each module is composedof input bandpass filters around f1 and f2 to suppress the possible crosstalks between each channel, anelectronic mixer, and an output bandpass filter around f1− f2. The bandwidth of the filters should allowto monitor the OPD variations of L1 and L2 imposed by the delay lines, the variable curvature mirror,and the differential delay line. The two heterodyne frequencies must be chosen separated enough tosuppress at the most the possible cross-talks. We selected therefore in [AD1] heterodyne frequencies off1 = 650kHz and f2 = 450kHz.
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4.3 Phasemeter
The phaseϕ1−ϕ2 is then measured with a custom designed phasemeter. The sinusoidal reference andprobe signals are first converted to square signals by means of limiting amplifiers. Then, the signalsare fed to a digital zero-crossing phasemeter. The time interval between leading edges of the referenceand probe signals is measured by means of binary counter and an internal clock. To avoid any driftbetween the superheterodyne frequency f1− f2 and the internal clock frequency fc, the internal clock isobtained from a phase-locked loop which multiplies the frequency f1− f2 by a factor of 1024, leading toa resolution of 2π/1024.
The phasemeter is combined with an optical fringe counter to achieve a very large dynamic range. Aninteger and fractional fringe number i and f is thus provided. These values can be accumulated over auser-defined integration time T by means of digital adders to average out some high frequency metrologyerrors.
4.4 Phase error compensation
The phase difference is rigorously given by
ϕ1−ϕ2 =4πν
c∆L− 4π∆ν
cL2. (4)
As already mentioned, the first term depends only on the differential optical path difference. However,the second term is sensitive to the individual optical path difference L2 of the reference interferometer.Since∆ν is small compared to the optical frequencyν, the phase difference is not very sensitive to L2.However, since the delay line can move over several meters during the observation, we have to takethis phase variation into account. The variation of L2 will therefore be estimated using the individualinterference signal I2(t) and its corresponding reference signal at frequency f2. It has been shown that asimple fringe counter is amply sufficient to compensate this error.
5 Design of the photodetectors
A typical photodetector circuit is depicted in Fig. 3. The resistor R fixes the transimpedance gain in V/A.Several sources of noise are inherent in the process of photodetection. The main contributions are: Shotnoise (i), Johnson noise (ii), and amplifier noise (iii). The performance of a photodetector is usuallycharacterized by its Noise Equivalent Power (NEP). For a Johnson noise limited detection, the NEP isgiven by
NEP=√
4kB T RR S1.3µm
(5)
where kB is the Boltzmann constant, T is the temperature and S is the sensitivity of InGaAs at 1.3µmin A/W. The spectral sensitivity of the photodiode is S= ηe/hν, where e is the electron charge,η is thequantum efficiency of the detector, andν the optical frequency. Since the quantum efficiency of InGaAsat 1.3µm is typically 0.8, the sensitivity at 1.3µm is about 0.88 A/W.
The photodiode is an InGaAs photodiode in FC receptacle (FD100FC), commercially available fromFermionics (CA), with a diameter of 100µm, a spectral sensitivity of 0.88 A/W at 1.3µm, a dark currentof max. 0.15 nA and a terminal capacitance of less than 1 pF.
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–
+UB
Vouti = S Popt
OPAhν
C0
R0
Figure 3: Transimpedance circuit. PD: photodiode; OPA: operational amplifier.
The design of the transimpedance circuit is based on an application note of Siliconix [AD3]. The op-erational amplifier consists of a discrete FET differential preamplifier followed by a monolithic bipolaroperational amplifier. This allows to use a relatively high bandwidth for a high transimpedance gain(1.4MΩ). Low-noise electronic components have been selected for optimal performance.
The photodetector has a bandwidth of 7.5 MHz and a noise level at 650 kHz of about -128 dBm/Hz(electrical power in 50Ω), corresponding to a noise equivalent power of about 0.14pW/
√Hz. This
value is very close to the Johnson noise limit at 300 K (0.12pW/√
Hz).
Table 2 summarizes the specifications of the photodetectors.
6 Design of the superheterodyne module
450 kHz
200 kHz
200 kHz
Mixer
Mixer
Imeas,1
650 kHz
Imeas,2
450 kHz
Iref,1
650 kHz
PreampFilter Limiter Mixer
Iref,2
Limiter
Limiter
Limiter
Limiter
Limiter
Limiter
Figure 4: Global design of the superheterodyne module.
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Photodiode 100µm InGaAs pigtailed
Response 800–1800 nm
Transimpedance gain 1.4×106V/A
Bandwidth DC to 7.5 MHz
Sensitivity 1.2V/µW
Output impedance 50Ω
Output voltage (50Ω) 0–1.7 V
Output voltage (Hi-Z) 0–3.4 V
Saturation level 1.4µW
Offset Adjustable
Noise (typical) from 10 Hz to 800 kHz -128 dBm/Hz
Noise (max) at 6 MHz -115 dBm/Hz
NEP at 1300 nm 0.14pW/√
Hz
Table 2: Summary of the photodetector specifications.
Figure 4 shows the global design of the superheterodyne module.
The superheterodyne module is composed of three boards:
• Photodetectors, preamplifiers and bandpass filters (PreampFilter);
• Limiting amplifiers (Limiter);
• Mixers (Mixer).
All boards use the±12V supply voltage available on the P1 connector of the VME crate. In orderto protect from the parasitic frequencies of the power supply, all the operational amplifiers used in thephasemeter are equipped with a low-pass filter on the +12 V and -12 V power supply lines. These RCfilters, with a bandwidth of around 3.2 kHz, reduce the parasitic frequencies of the switching powersupply (typically ranging from 150 to 800 kHz) with an attenuation better than 34 dB.
On the front panels, the inputs are SM-A connectors and the outputs are LEMO CAMAC unipolar Series00 connectors.
6.1 Preamplifiers and filters
After detection, the four signals are filtered using bandpass filters at 450 and 650 kHz. The preamplifiersconsist of one amplifiers at the input of the filter and one at the output. This configuration ensures inputand output impedances of 50Ω for the filters and thus prevent problems due to impedance mismatchbetween the different building blocks of the superheterodyne module. The gain of the input and outputamplifiers is of 23.6 dB and 11.6 dB, respectively.
The electronic circuits of the filters (tenth order Chebyshev filters) are shown in Annex B. Because of themovement of the delay lines, the heterodyne frequencies may vary from 425 kHz to 475 kHz and from
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625 kHz to 675 kHz. The bandwidth of the filters must therefore be wide enough to pass these rangesof frequencies. According to the specification [AD4], the bandwidth will be of 110 kHz (±55kHz)for the input filters and of 55 kHz (±27.5kHz) for the output filters. It is also important for the phaseresponse of a pair of filters (one filter at 450 kHz and one at 650 kHz) to be as identical as possibleover their bandwidth in order to minimize the phase shifts introduced by the variation of the heterodynefrequencies during delay lines movement. Therefore, all the selfs in the filters are tunable, making itpossible to match the phase response of each pair of filters.
For testing purposes, it is possible to unplug the photodetectors and enter an electric signal on the boardinstead. The input will have to be switched manually by unplugging the photodetector cable on theboard and plugging the electrical input instead (dashed line in Annex A). A parking connector will beavailable on the board to secure the unused cable. This mechanism was chosen instead of a relay becauseof the bandwidth limitation of standard relay components. The electrical inputs will be protected fora maximum voltage of 15 Vpp using diodes. In addition, the photodetector output (DC coupled) isavailable on the front panel for monitoring.
The DC level of the photodetector is made available after a lowpass filter to be digitized on the digitalphase meter board (see 7.6).
Table 3 lists the input and outputs of the PreampFilter board.
6.2 Limiting amplifiers
The filtered heterodyne signals are converted to square signals using a limiter stage before the mixerstage. There are two benefits to using square signals:
• The mixing efficiency is higher compared to sinusoidal signals;
• The mixing efficiency depends on the amplitude of the input signals. A square signal of constantamplitude at the input of the mixer board makes it possible to adjust the amplitude of the signalsfor maximum efficiency using an amplifier with a variable gain at the mixer input.
The limiting amplifier is composed of two stages. The first stage amplifies the signal with a high gainand limits the amplitude using diodes. The second stage is a comparator that delivers a square signal inTTL format.
The 450 kHz reference and probe signals are also provided on a second output for the error compensationfringe counter on the digital phasemeter board.
Another signal is generated on this board and will be used to provide status information on the hetero-dyne frequencies (see 7.6). A buffer with a high input impedance is used to take a part of the input signal.A window comparator then converts the signal into a square signal that will be used for frequency mea-surement on the digital board and also introduces a threshold voltage under which the it gives no output,meaning that the amplitude of the heterodyne signal is too low. The threshold voltage will be adjustable.
Table 4 lists the input and outputs of the Limiter board. The electronic circuits are shown in Annex C.
6.3 Mixers
At each input of the mixer, an AC amplifier with an adjustable gain is used to remove the DC componentof the input TTL signal and adjust its amplitude for maximum mixing efficiency. The gain is adjustedusing a potentiometer located on the board.
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Input Description Location Connector
Ref
INOPT1 Optical input for the 450 kHz reference signal Front SM-A
INOPT2 Optical input for the 650 kHz reference signal ” SM-A
INEL1 Electrical input for the 450 kHz reference signal ” SM-A
INEL2 Electrical input for the 650 kHz reference signal ” SM-A
Probe
INOPT1 Optical input for the 450 kHz probe signal Front SM-A
INOPT2 Optical input for the 650 kHz probe signal ” SM-A
INEL1 Electrical input for the 450 kHz probe signal ” SM-A
INEL2 Electrical input for the 650 kHz probe signal ” SM-A
Electrical inputs Nominal value 3 dBm (0.9Vpp)
Maximal value 8 dBm (1.6Vpp)
Destruction value 27 dBm (15Vpp)
Output Description Location Connector
Ref
OUT 450kHz 450 kHz filtered reference signal Front LEMO
OUT 650kHz 650 kHz filtered reference signal ” LEMO
DET1 OUT Photodetector output of the 450 kHz reference signal ” LEMO
DET2 OUT Photodetector output of the 650 kHz reference signal ” LEMO
DC REF 450kHz DC level of the 450 kHz reference signal Back (P2) DIN 41612
DC REF 650kHz DC level of the 650 kHz reference signal ” DIN 41612
Probe
OUT 450kHz 450 kHz filtered probe signal Front LEMO
OUT 650kHz 650 kHz filtered probe signal ” LEMO
DET1 OUT Photodetector output of the 450 kHz probe signal ” LEMO
DET2 OUT Photodetector output of the 650 kHz probe signal ” LEMO
DC PROBE 450kHz DC level of the 450 kHz probe signal Back (P2) DIN 41612
DC2 PROBE 650kHz DC level of the 650 kHz probe signal ” DIN 41612
Table 3: Input and outputs of the preamplifiers and filters board. SM-A: SM-A female; LEMO: LEMOCAMAC unipolar series 00; DIN 41612: DIN 41612 3×32 male.
In the prototype version of the phasemeter, there was an impedance mismatch between the output of themixer and the input of the 200 kHz filter. Indeed, the input impedance of the filter was of 50Ω for a200 kHz signal, but increased as the frequency differed from the bandpass frequency. In consequence,the frequencies of 450, 650 and 1100 kHz at the output of the mixer (remains of the input signals and sumof the frequencies) were reflected back into the latter and mixed again with the other signals, generatingadditional, parasitic components with a frequency of 200 kHz.
To work around this problem, buffers were added to the filters input and output in order to match theimpedance to 50Ω for all the frequencies. Moreover, in order to simplify their design, the same schematicwas used for all the bandpass filters. Therefore, the preamplifiers needed on the 450 and 650 kHz chan-nels were implemented as input and output buffers, splitting the gain between both stages, as describedearlier.
The output of the mixer is filtered at 200 kHz with a bandwidth of 55 kHz. The design of the 200 kHzfilter is the same as the 450 and 650 kHz filters, with amplifiers at the input and output that ensure a
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Input Description Location Connector
RefA IN 450kHz 450 kHz filtered reference signal Front SM-A
A IN 650kHz 650 kHz filtered reference signal ” SM-A
ProbeA IN 450kHz 450 kHz filtered probe signal Front SM-A
A IN 650kHz 650 kHz filtered probe signal ” SM-A
Only use the output signals from the preamplifiers and filters board as inputs
Output Description Location Connector
Ref
D OUT 450kHz 450 kHz digital reference signal Front LEMO
D OUT 650kHz 650 kHz digital reference signal ” LEMO
FC OUT 450 kHz digital reference signal for fringe counter ” LEMO
MESR 450kHz 450 kHz reference output for frequency measurement Back (P2) DIN 41612
MESR 650kHz 650 kHz reference output for frequency measurement ” DIN 41612
Probe
D OUT 450kHz 450 kHz digital probe signal Front LEMO
D OUT 650kHz 650 kHz digital probe signal ” LEMO
FC OUT 450 kHz digital probe signal for fringe counter ” LEMO
MESP 450kHz 450 kHz probe output for frequency measurement Back (P2) DIN 41612
MESP 650kHz 650 kHz probe output for frequency measurement ” DIN 41612
Table 4: Input and outputs of the limiting amplifiers board. SM-A: SM-A female; LEMO: LEMOCAMAC unipolar series 00; DIN 41612: DIN 41612 3×32 male.
proper impedance matching and amplify the signal before conversion to the TTL format. Since themixer is working at constant amplitude, the amplification on final limiter stage can be reduced comparedto the prototype, where the large range of input amplitudes required several amplificating stages on thelimiter before the comparator.
Table 5 lists the input and outputs of the Mixer board. The electronic circuits are shown in Annex D.
7 Design of the digital phasemeter
The digital phasemeter is composed of 6 subsystems:
1. Phase-locked loop
2. Phase shifter
3. Digital zero-crossing phasemeter
4. Phase adder
5. Error compensation fringe counter
6. Status registers
A schematic of the digital phasemeter is shown in Annex E.
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Input Description Location Connector
RefD IN 450kHz 450 kHz digital reference signal Front SM-A
D IN 650kHz 650 kHz digital reference signal ” SM-A
RefD IN 450kHz 450 kHz digital probe signal Front SM-A
D IN 650kHz 650 kHz digital probe signal ” SM-A
Only use the output signals from the limiting amplifiers board as inputs
Output Description Location Connector
Ref D OUT 200kHz 200 kHz digital reference signal Front LEMO
Probe D OUT 200kHz 200 kHz digital probe signal Front LEMO
Table 5: Input and outputs of the mixers board. SM-A: SM-A female; LEMO: LEMO CAMAC unipolarseries 00.
7.1 Phase-locked loop
The phase-locked loop is composed of a high-frequency voltage-controlled oscillator (200 MHz) and aphase comparator circuit. The VCO frequency is first divided by 1024 to obtain a signal of roughly200 kHz. An Altera PLD is used for this purpose. The phase of the frequency divided signal is thencompared to the phase of the reference signal of 200 kHz frequency. The output of the phase comparatoris low-pass filtered by a simple RC filter (about 1 MHz cut-off frequency) and then fed back to the VCO.In the phasemeter prototype, the circuit showed a phase jitter of only a few ns.
7.2 Phase shifter
The phase shifter module is used to a reference signal shifted byπ/2 in order to solve the problemencountered with phase values close to zero. It is described in [AD3]. At each raising edge of thereference signal, the counter is enabled. After 256 counts, a pulse is generated, leading to a signal(RefQ) phase shifted byπ/2 relative to the reference signal, assuming the ratio between the clock andreference frequencies is of 1024.
7.3 Digital zero-crossing phasemeter
The principle of the digital zero-crossing phasemeter is described in [AD1]. The design is based on thedesign of the phasemeter prototype, described in [AD3].
When the raising edge of the reference is detected, a 10-bit counter is started. When the raising edge ofthe probe signal is detected, the counter is stopped and the value latched. The same process is applied ina second channel, identical to the first one except that it uses the second reference signal, shifted byπ/2.A multiplexer is used to select the value used for the output, based on the value of the first channel.
A third counter is used to count the number of 2π phase cycles. To monitor a distance of 120 mm, a18-bit counter should be sufficient. For safety, a 19-bit counter was implemented. The total width of theinstantaneous phase is therefore 29 bits.
For testing purpose, the instantaneous phase will be provided on the front panel, using a AMP 2-174225-5 type connector. The pinout corresponds to the National Instruments PCI DIO/32 H digital I/O boardand is presented in annex. The output frequency will be of 200 kHz.
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7.4 Phase adder
In the phasemeter prototype, an on-board averaging function was implemented in programmable logic.In order to simplify the calculations, the averaging could be performed over a number of samples thatwas a power of 2, between 4 and 131072.
In the final version of the phasemeter, it is desired to be able to average data on an arbitrary numberof samples between 25 and 400000, corresponding to an output data rate between 0.5 Hz and 8 kHz.Therefore, the phase adder module performs the sum of the instantaneous phase between two triggersignals from the TIM. This sum and the number of samples summed will be transferred to the LCU,which will perform the division to obtain the average value. The width of the sum is of 48 bits.
The concept of the phase adder is shown in fig. 5. Between two consecutive trigger signals, the instan-taneous phase (IP[0..28]) coming from the instantaneous phasemeter is added by means of a full adder.Simultaneously, a classical counter counts the number of “REQ” signals coming from the instantaneousphasemeter (The REQ signal is active as soon as the output value of the instantaneous phasemeter isupdated). The reset signal allows to reset the full adder and the counter. The output of the full adder issplit in two 32-bit words. The output length of the counter is also of 32 bits. The three 32-bit words feedthen a bus multiplexer, which is driven by two address bits A0 and A1. Depending on the values of A0and A1, one of the three words is selected by the bus multiplexer. An output enable signal (OE) is thenused to drive the output Q[0..32] to the data bus of the phasemeter board.
Full adder
Busmulti-plexer
Counter
OE
A0A1
IP[0..28]
TRIG
REQ
CLK
AP[0..63]
N[0..31]
RESET
Q[0..31]
AP[0..31]
AP[32..63]
Start/stop
Start/stop
Figure 5: Concept of the phase adder.
7.5 Error compensation fringe counter
The principle of the error compensation fringe counter is described in [AD1]. The design is described in[AD3].
The error compensation fringe counter is based on an up/down counter. The output value is incremented
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by the reference signal and decremented by the probe signal. Since the delay lines may travel over severalmeters, a 24-bit output is required. This allows to measure a maximal displacement of 224×660nm=11m.
7.6 Status registers
Status of interferometric signals
The frequency of the four heterodyne signals will be measured using PIC12 microcontrollers (Microchip,USA). These microcontrollers feature an internal 4 MHz clock, an 8-bit real time counter and an 8-bitprescaler. The input frequency is divided by 16 and gated for a duration of 5 ms. The frequency can becalculated with an accuracy of 3.2 kHz from the value of the counter at the end of the measurement. Theoutput is set to 1 if the frequency is within the accepted range, 0 otherwise. The microcontrollers will beprogrammed in assembly language on PROM devices, therefore requiring no maintenance.
The status of the reference 200 kHz signal is determined from the PLL locked output of the PLL circuit.The status of the probe 200 kHz signal is determined in the phase shifter module using a circuit based onthe principle of the watchdog timer. The value of a flip-flop is set by the raising edge of the probe signaland reset by a clock of lower frequency. As long as the probe signal is present, the output is 1. When theprobe signal is absent, the output falls to 0.
Signal level of the photodetectors
The DC level of each photodetector, obtained from the preamplifiers and filters board, will be digitizedover 8 bits. The analog to digital conversion will be performed using four 8-bit, one channel digital toanalog converters (Maxim Integrated Products MAX152 or similar) with a voltage reference of 1.8 Vprovided by an external voltage reference (Maxim Integrated Products MAX6100 or similar). Therefore,the resolution on the DC level of the photodetector will be of 1LSB= 7mV, corresponding to an opticalpower of 5.7 nW.
Other status signals
The other status bits provided are:
• Overflow of the instantaneous phase counter
• Overflow of the error compensation fringe counter
• Trigger detected
• Reset detected
All the status signals are collected into two 32-bit buffers in the format shown of fig. 6.
7.7 Data transfer
There are four different values that must be transferred between the phasemeter and the LCU:
OS, 28.8.2003 Institute of Microtechnology, Neuchâtel
15
1. Summed phase (1LSB= 2π/1024rad)
2. Error compensation (1LSB= 0.66µm)
3. Number of samples
4. Status
The data will be transmitted over 6 packets of 32 bits using the format shown of fig. 6. Figure 7 showsthe timing diagram of the data transfer.
The packet counter is a 4-bit counter that is incremented for each packet. It is present in the first andlast data words. Block integrity and sequentiality checks are performed on the Start Of Block (SOB) andEnd Of Block (EOB) bytes, the first and last byte of the packet, respectively:
• Block integrity: SOB xor EOB= 1
• Block sequentiality: SOB(i) = (SOB(i−1)+0x10) & 0xFF
The six 32-bit words will be made available sequentially on a 32-bit bus. A strobe signal will be issuedwhen each word is ready. The data will be read on the LCU using a PMC-HPDI32 digital IO card. Thesignals will be converted to RS422/485 format using differential line drivers and made available on aconnector of type Robinson Nugent #P50E-080-S-TG on the back side of the P2 backplane. Two LEMOSeries 00 connectors next to it will receive the trigger and reset signals from the TIM.
Table 6 lists the input and outputs of the Phasemeter board and table 7 summarizes the units used.
8 Design summary
The OPDU will be manufactured on four 6HE VME boards, to comply with ESO standards. Thephasemeter will consist of 4 VME boards. The first one will be devoted to the phototdetectors andinput bandpass filters, the second one will contain the limiting amplifiers, the third one will contain themixers and output bandpass filters and the last one will be dedicated to the digital phasemeter, the errorcompensation fringe counter and the interface with the LCU. Each board will have extraction handles.The front panel cables will be labelled to facilitate the cabling of the phasemeter. The sketch of thecomplete phasemeter is shown in Annex A, the schematics of the boards are shown in Annexes B-E andthe layouts of the front panel and backplane are shown in Annexes F and G.
Institute of Microtechnology, Neuchâtel OS, 28.8.2003
16
33
931313131
5047
23
18
33M
SB31
00
2219
48
70
70
70
70
09
87
65
43
21
0 000032LSB 0
024
028
SOT
DC
Ref
450
kD
C P
rob
e 45
0kD
C R
ef 6
50k
DC
Pro
be
650k
Pack
et #
Pack
et #
EOT
Zer
o p
add
ing
(5 b
its)
Zer
o p
add
ing
(14
bit
s)
Phas
e su
m
Phas
e su
m
Nu
mb
er o
f sam
ple
s
Erro
r co
mp
ensa
tio
n
Stat
us
I
Stat
us
I
Stat
us
II
Stat
us
II
450k Ref detected
650k Ref detected
PLL Locked
200k Probe detected
PM Overflow
Trigger detected
Reset detected
FC Overflow
450k Probe detected
650k Probe detected
Figure 6: Data transfer format.
OS, 28.8.2003 Institute of Microtechnology, Neuchâtel
17
Timing diagram of the digital phasemeter
t
d
t
1
Trig
REQ
START
STOP
STROBE
OE1
A0
A1
OE2
OE3
OE4
• Level high!: 3.3 V (TTL compatible)
• Timing
Unit Min Max Remarkt1 µs 0.2 5.2 Variabled µs 0.35 1 Programmablet µs 0.25 1 Programmable
Figure 7: Timing diagram of the data transfer.
Institute of Microtechnology, Neuchâtel OS, 28.8.2003
18
Input Description Location Connector
Ref
D IN 200kHz Input of the 200 kHz reference signal Front SM-A
FC IN Input of the 450 kHz reference signal ” SM-A
DC REF 450kHz DC level of the 450 kHz reference signal Back (P2) DIN 41612
DC REF 650kHz DC level of the 650 kHz reference signal ” DIN 41612
MESR 450kHz 650 kHz reference signal for frequency measurement ” DIN 41612
MESR 650kHz 650 kHz reference signal for frequency measurement ” DIN 41612
Probe
D IN 200kHz Input of the 200 kHz probe signal Front SM-A
FC IN Input of the 450 kHz probe signal ” SM-A
DC PROBE 450kHz DC level of the 450 kHz probe signal Back (P2) DIN 41612
DC PROBE 650kHz DC level of the 650 kHz probe signal ” DIN 41612
MESP 450kHz 650 kHz reference signal for probe measurement ” DIN 41612
MESP 650kHz 650 kHz reference signal for probe measurement ” DIN 41612
Trig Trigger signal from TIM Back (P2) LEMO
Reset Reset signal from TIM ” LEMO
All input signals must be 0−5V TTL compatible signals.
Output Description Location Connector
Inst Phase Instantaneous phase Front AMP 2-174225-5
Data bus 32-bit data bus, balanced Back (P2) Robinson
Strobe Strobe signal for data bus transfer ” Robinson
Table 6: Input and outputs of the digital phasemeter board. SM-A: SM-A female; LEMO: LEMO CA-MAC unipolar series 00; DIN 41612: DIN 41612 3×32 male; AMP 2-174225-5 2×34 male; Robinson:Robinson Nugent #P50E-080-S-TG.
Value Size Unit
Summed phase 48 bits 1LSB= 2π/1024rad
Error compensation 24 bits 1LSB= 0.66µm
Signal level of photodetectors 8 bits 1LSB= 7mV
Table 7: Units used for the values on the data bus.
Instantaneous phasemeter resolution 2π/1024
Internal sampling rate 200 kHz
Noise Equivalent Power of the photodetectors 0.14pW/√
Hz
Bandwidth of the input filters 110 kHz(±55kHz)
Saturation level of the photodetectors 1.4µW (optical) or 1.7 V
Nominal value of electrical inputs (INEL1/2, Probe/Ref) 0 dBm
Maximum value of electrical inputs (INEL1/2, Probe/Ref)27 dBm
Table 8: Summary of the phasemeter performance
OS, 28.8.2003 Institute of Microtechnology, Neuchâtel
19
9 Experimental tests
9.1 Electrical tests
Test of the phasemeter board
Two frequency generators with their time base locked to each other will be used to generate two squaresignals at 200 kHz. The phase between the signals will be varied and the instantaneous phase will bemonitored.
Test of the whole system
The same frequency generators will be used to generate sine signals at 450 and 650 kHz fed to theelectrical inputs of the preamplifiers and filters board. The phase between the signals will be varied andthe instantaneous phase output of the phasemeter will be monitored. The test will be repeated for differentinput levels. The corresponding optical power in each arm can then be calculated and the minimal opticalpower required for proper operation of the phasemeter can be deduced.
9.2 Dynamic tests
Target
Reference Mirror
l/4
Is(t)Ir(t)l1
AOM
AOM
PBS
PBS
BS PBS
PBS
P PL
OPDU
Translation stage or loudspeaker
Figure 8: Simulation of the motion of the delay lines.
Figure 8 shows the setup that will be used to simulate the movement of the delay lines. The commonpath will be modulated by means of a translation stage or a loudspeaker.
Figure 9 shows the setup that will be used to simulate the movement of the differential delay line. TheOPDU should be able to monitor the displacement of the mirror moving with a speed of 15 mm/s.
9.3 Tests of accuracy
Because of the stringent requirements, the test of accuracy over 120 mm with a one-wavelength sourceis a very difficult task. This would require a mechanical stability better than 5 nm. This stability is very
Institute of Microtechnology, Neuchâtel OS, 28.8.2003
20
Target
Reference Mirror
Is,1(t)Ir,1(t)l1
AOM
AOM
PBS
PBS
BS PBS
PBS
P PL
Translation stage or loudspeaker
Is,2(t)
Ir,2(t)
Figure 9: Simulation of the motion of the differential delay line.
Target
Reference Mirror
l/4
Is(t)Ir(t)l1
l2
AOM
AOM
PBS
PBS
BS PBS
PBS
P PL
Figure 10: Two-wavelength interferometry with superheterodyne detection.
difficult to obtain in laboratory. In addition, the refractive index of the air must be controlled to achievethe required 10−8 accuracy.
Two-wavelength interferometry allows to generate synthetic wavelengthsΛ = c/∆ν much longer thanthe individual optical wavelength. This allows to extend the range of non-ambiguity and to reduce thesensitivity of the measurement. The mechanical stability at the optical wavelength is thus not requiredany more. For instance, assuming a synthetic wavelength of 200 mm, a mechanical stability of 0.1 mmis required to demonstrate 2π/1000. This mechanical stability is obviously easy to achieve in laboratory.The setup depicted in Fig. 10 will be used for these tests.
The Nd:YAG lasers will be stabilized at a frequency difference of 1.5 GHz, corresponding to a syntheticwavelength of 200 mm by measuring the beat frequency resulting from the superposition of the two laserbeams.
9.4 Tests by comparison with a HP interferometer
In order to check the accuracy of the metrology prototype in a polarizing configuration, we can measurethe variations of a common optical path difference using both the metrology prototype and an industrial
OS, 28.8.2003 Institute of Microtechnology, Neuchâtel
21
HP laser
PBSC C
C C
HP det.
PBS
PBS
n-40 MHz
n-39.55 MHz
n+38.65 MHz
n+38 MHz
Probe 450 kHz
Ref 450 kHz
Probe 650 kHz
Ref 650 kHz
FC
Figure 11: Setup that will be used for tests by comparison with a HP interferometer. PBS, polarizingbeamsplitter; CC, corner cube; FC, fiber coupler; HP det, Hewlett-Packard detector.
interferometer (Hewlett-Packard 5517A). Figure 11 shows the setup that will be used.
9.5 Tests with long delay lines
The setup of Fig. 12, using a 1 km long fiber, can be used to simulate a long baseline interferometer. Thetwo heterodyne interferometers share a common optical path difference of 1.5 km. The observation ofthe phase of the individual 450 and 650 kHz signal as well as the phase difference makes it possible todetermine the fluctuations of the phase difference.
Institute of Microtechnology, Neuchâtel OS, 28.8.2003
22
n+38.65 MHz
n-39.55 MHz
n-40 MHz
n+38 MHz
Ref 450 kHz
Ref 650 kHz
FC
Probe 450 kHz
Probe650 kHz
FC
1 km fiber delay
PC
P
P
Figure 12: Setup that will be used to simulate long delay lines. P, polarizer; FC, fiber coupler; PC,polarization controller.
OS, 28.8.2003 Institute of Microtechnology, Neuchâtel
Institute of Microtechnology, Neuchâtel OS, 27.3.2003
A
Annex A
Global sketch of the phasemeter
Synoptique.Sch
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10/01/03Phase mètre : Schéma synoptique
Rue A.-L. Breguet 22000 Neuchâtel
Photodetector
MixerU8
SRA-6
ZsZe
5050
U7
G=11.6 dB
F1
450 kHz
ZsZe
50HI
U9
G= 0 dB
Low pass filter
40 kHz
ZsZe
5050
U3
G=12 dB
Converter
TTL
TTL
U12
INOPT1
INEL1
DET1 OUT
OUT 450 kHz D OUT 450 kHz
DC REF 450K
1.2 V/u W
InGaAs
INOPT2
INEL2
DET2 OUT
Windowcomparator
TTL
Adj
U4
ZsZe
50HI
U2
G=0 dB
Converter
TTL
TTL
U12
OUT 650 kHz
DC REF 650K
MESR 450 kHz
G=-7dB
J14-B1
J14-A1
PROBE
REF
ZsZe
50HI
U8
G=28.8 dB
TV1
G=13 dB
J2-A2
FC OUT
A IN 450 kHz
D OUT 650 kHz
Windowcomparator
TTL
Adj
U5
ZsZe
50HI
U10
G=0 dB
Converter
TTL
TTL
U13
MESR 650 kHz
ZsZe
50HI
U16
G=28.8 dB
TV3
G=13 dB
J2-B2
A IN 650 kHz
MESP 450 kHz
J2-C3
MESP 650 kHz
J2-C4
TV1
G=12 dB
Band pass filter AmplifierZsZe
5050
U5
G= 11.6 dB
Amplifier
Photodetector ZsZe
5050
U13
G=11.6 dB
F2
650 kHz
ZsZe
50HI
U15
G= 0 dB
Low pass filter
40 kHz
1.2 V/u W
InGaAs
G=-7dB
TV2
G=12 dB
Band pass filter AmplifierZsZe
5050
U11
G= 11.6 dB
Amplifier
LIMITER
PROBE
DC PROBE 450K
DC PROBE 650KJ14-C2
J14-C1
AC Limiting Amplifier Amplifier
Buffer
TV1
G=0 dB
ZsZe
5050
U2
G= AdJ
Amplifier
AmplifierF1
200 kHz
G=-7dB
Band pass filter
ZsZe
5050
U4
G= Adj
AmplifierD OUT 200 kHz
D IN 450 kHz
TV2
G=0 dB
ZsZe
5050
U10
G= AdJ
AmplifierD IN 650 kHz
Photodetector ZsZe
5050
U8
G=11.6 dB
F3
450 kHz
ZsZe
50HI
U10
G= 0 dB
Low pass filter
40 kHz
INOPT1
INEL1
DET1 OUT
OUT 450 kHz
1.2 V/u W
InGaAs
INOPT2
INEL2
DET2 OUT
OUT 650 kHz
G=-7dB
TV3
G=12 dB
Band pass filter AmplifierZsZe
5050
U6
G= 11.6 dB
Amplifier
Photodetector ZsZe
5050
U14
G=11.6 dB
F4
650 kHz
ZsZe
50HI
U16
G= 0 dB
Low pass filter
40 kHz
1.2 V/u W
InGaAs
G=-7dB
TV4
G=12 dB
Band pass filter AmplifierZsZe
5050
U12
G= 11.6 dB
Amplifier
D OUT 450 kHz
FC OUT
A IN 450 kHz
D OUT 650 kHzA IN 650 kHz
MixerU9
SRA-6
ZsZe
5050
U6
G=12 dB
Converter
TTL
TTL
U13
TV3
G=0 dB
ZsZe
5050
U5
G= AdJ
Amplifier
AmplifierF2
200 kHz
G=-7dB
Band pass filter
ZsZe
5050
U7
G= Adj
AmplifierD OUT 200 kHz
D IN 450 kHz
TV4
G=0 dB
ZsZe
5050
U11
G= AdJ
AmplifierD IN 650 kHz
MIXER
REF REF REF
PROBE
PROBE
D IN 200 kHz
FC IN
TRIG
RESET
D IN 200 kHz
FC IN
DIGITAL PM
PREAMPFILTER
Buffer
Buffer
Buffer
Buffer
AC Limiting Amplifier Amplifier
Buffer
Windowcomparator
TTL
Adj
U6
ZsZe
50HI
U3
Converter
TTL
TTL
U14
ZsZe
50HI
U9
G=28.8 dB
TV5
G=13 dB
Windowcomparator
TTL
Adj
U7
ZsZe
50HI
U11
G=0 dB
ZsZe
50HI
U17
G=28.8 dB
TV7
G=13 dB
AC Limiting Amplifier Amplifier
Buffer
AC Limiting Amplifier Amplifier
Buffer
Converter
TTL
TTL
U15
G=0 dB
OverLoadProtection
OverLoadProtection
OverLoadProtection
OverLoadProtection
J66
Institute of Microtechnology, Neuchâtel OS, 27.3.2003
B
Annex B
Schematic circuits of
the Preampfilter board
PreampFiltre.prj
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PreampFiltre: canal REF + canal PROBE
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA10/01/03
30114
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J1
Vin3
AD
J1
+Vout 2U2
LM317
Vin2
AD
J1
-Vout 3
U4
LM337
R7100R
R8100R
R34.7k
R44.7k
C2410uF
C2310uF
C272.2uf
C282.2uf
GND
GND
GND
GND
GNDGND
GND
GND
+5V-2
-5V-2
+12V-12V
C20100nF
C19100nF
P25k
C4220uF
C3220uF
C17100nF
C18100nF
Vin3
AD
J1
+Vout 2U1
LM317
Vin2
AD
J1
-Vout 3
U3
LM337
R5100R
R6100R
R14.7k
R24.7k
C2210uF
C2110uF
C262.2uf
C252.2uf
+5V-1
-5V-1
C14100nF
C16100nF
P15k
C2220uF
C1220uF
C13100nF
C15100nF
1234
J2
1234
J3
1234
J4
1234
J5
V+
V-
GND
PreampFiltre 450kHzPreampFiltreRef.Sch
GND
GND
+12V
GND
-12V
+12VGND-12V
V+
GND
V-
PreampFiltreProbePreampFiltreProbe.Sch
+12V
GND
-12V
D11N4148
D21N4148
J23
J24
J25
J26
J27
J28
Alimentations
PreampFiltreRef.Sch
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PreampFiltre: canal REF
Rue A.-L. Breguet 22000 Neuchâtel
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J6E1 S1
E2 S2
F1
450kHz
E1
E2 S2
S1V+
V-
U7
Ampli (1) 450kHz
6 1
5 2
4 3
TV1
T16-6T
PT1R9
0R
R10
0R
PT2
GND
GND
GNDGND GND GND GND GNDGND
C29
100nf
C5
220uF
C30
100nf
C6
220uF
GND
C31
100nf
C7
220uF
C32
100nf
C8
220uF
GND
V+
GND
V-
V+ V+
V+
V- V-
V-
V-
V+
GND
GND
E1 S1
E2 S2
F2
650kHz
E1
E2 S2
S1V+
V-
U13
Ampli (1) 650kHz
6 1
5 2
4 3
TV2
T16-6T
PT3R11
0R
R12
0R
PT4
GND
GND
GNDGND GND GND GND GNDGND
V+ V+
V+
V- V-
V-
GND
E1
E2 S2
S1V+
V-
S3
U5
Préampli (2) 450kHz
E1
E2 S2
S1V+
V-
S3
U9
Préampli (3A) 450kHz
E1
E2 S2
S1V+
V-
S3
U11
Péampli (2) 650kHz
E1
E2 S2
S1V+
V-
S3
U15
Préampli (3A) 650kHz
GND
GND
J16
GND
GNDR41 100R
R42 100R C5382nF
C5482nF
GNDGND
J15
R43 100R
R44 100R
OUT 450 kHz
DET1 OUT
DET2 OUT
OUT 650 kHz
INOPT1
INOPT2
INEL1
INEL2
GND
C5682nF
C5782nF
GND GND
L1228 uH
L2228 uH
GND
GND
DC REF 450K
DC REF 650K
PreampFiltreIntfPreampFiltreIntf.Sch
A=3,8
A=3.8
A=1
A=1
A=3,8A=0.44
A=3.8
FC= 40 kHz
FC= 40 kHz
Preampli + Filtre (450 kHz, 650 kHz)
A= 0.44
R17 50R
D3 BAR43S
R18 50R
GNDGND
J7
GND
J53
Photodetector
J57
J32J29
J17
J18
J35
J30
J33J31
J37J36
J40J39
J8
GND
GND
R19 50R
D4 BAR43S
R20 50R
GNDGND
J9
GND
J54
Photodetector
J58
J34
J38
Front PanelFront Panel
PreampFiltreIntf.Sch
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PreampFiltre: canal REF + canal PROBE
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA10/01/03
30114
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J14
DC REF 450K
DC PROBE 650K
DC PROBE 450K
DC REF 650K
A1
B1
C1
C2
A1
B1
C1
C2
Interface
PreampFiltreProbe.Sch
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E1 S1
E2 S2
F3
450kHz
E1
E2 S2
S1V+
V-
U8
Ampli (1) 450kHz
6 1
5 2
4 3
TV3
T16-6T
PT5R13
0R
R14
0R
PT6
GND GNDGND GND GND GND GNDGND
C33
100nf
C9
220uF
C34
100nf
C10
220uF
GND
C35
100nf
C11
220uF
C36
100nf
C12
220uF
GND
V+
GND
V-
V+ V+
V- V-
V-
V+
E1 S1
E2 S2
F4
650kHz
E1
E2 S2
S1V+
V-
U14
Ampli (1) 650kHz
6 1
5 2
4 3
TV4
T16-6T
PT7R15
0R
R16
0R
PT8
GND GNDGND GND GND GND GNDGND
V+ V+
V- V-
E1
E2 S2
S1V+
V-
S3
U6
Préampli (2B) 450kHz
E1
E2 S2
S1V+
V-
S3
U12
Préampli (2B) 650kHz
GND
V+
V-
GND
GND
V+
V-
GND
E1
E2 S2
S1V+
V-
S3
U10
Preampli (3A) 450kHz
E1
E2 S2
S1V+
V-
S3
U16
Preampli (3A) 650kHz
R45 100R
R46 100R
R47 100R
R48 100R
C5982 nF
C6082 nF
GND GND
L3228 uH
C6282 nF
C6382 nF
GND GND
L4228 uH
GND
GND
DC PROBE 450K
DC PROBE 650K
PreampFiltreIntfPreampFiltreIntf.Sch
FC= 40 kHz
FC= 40 kHz
A=3,8
A=3.8
A=1
A=1
A=3,8A=0.44
A=3.8A= 0.44
Preampli + Filtre (450 kHz, 650 kHz)
J10
GND
GND
GND
J20
GND
GND
GND
J19OUT 450 kHz
DET1 OUT
DET2 OUT
OUT 650 kHz
INOPT1
INOPT2
INEL2
R21 50R
D5 BAR43S
R22 50R
GNDGND
J11
GND
J55
Photodetector
J59
J44J41
J21
J22
J47
J42
J45J43
J49J48
J52J51
J12
GND
GND
R23 50R
D6 BAR43S
R24 50R
GNDGND
J13
GND
J56
Photodetector
J60
J46
J50
Front PanelFront Panel
INEL1
Ampli1PreampFiltre.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:16:40
PreampliFiltre : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA18/02/02
20218A
R622
C3
100nf
C5
2.2uf
C6
2.2uf
C9
2.2uf
C10
2.2uf
+V1 +V2
-V1 -V2
PT10
GND
V+
V-
R2100
GND
V-
4
IN3 OUT 6
BW 1NC2
NC5 NC 8
V+
7U2BUF634UR3
150
R8
680
R101500
C23.9 pf
C16.8 pf
GND
R4100
R9
390
+V1 +V2
-V1 -V2
P110k
V-
4
IN-2 IN+3 OUT 6
NC 5NC1
8
V+
7U1THS3001
E1 S1
E2
S2
S3
NB: All Résistances values in Ohms /Tol. 1% P1, C2, C1, PT10, No ConnectedA= 3,8 =>G=11,6 dB
C4
100nf
C8
100nf
C7
100nf
R1100 R5
100
R722
R1222
R1122
Preampli (1), [U7,U8,U13,U14]
Preampli2PreampFiltre.Sch
TITREDessinéDate
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/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:20:02
PreampliFiltre : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA18/02/02
20218A
R622
C3
100nf
C5
2.2uf
C6
2.2uf
C9
2.2uf
C10
2.2uf
+V1 +V2
-V1 -V2
PT10
GND
V+
V-
R21.5k
GND
V-
4
IN3 OUT 6
BW 1NC2
NC5 NC 8
V+
7U2BUF634UR3
150
R8
680
R101500
C23.9 pf
C16.8 pf
GND
R4100
R9
390
+V1 +V2
-V1 -V2
P110k
V-
4
IN-2 IN+3 OUT 6
NC 5NC1
8
V+
7U1THS3001
E1 S1
E2
S2
S3
NB: All Résistances values in Ohms /Tol. 1% P1, C2, C1, PT10, No ConnectedA= 3,8 =>G=11,6 dB
C4
100nf
C8
100nf
C7
100nf
R11.8k R5
100
R722
R1222
R1122
Preampli (2), [U5,U6,U11,U12]
Preampli3PreampFiltre.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:19:18
PreampliFiltre : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA18/02/02
30225A
+V1 +V2
-V2
S1
V-
4
IN3 OUT 6
BW 1NC2
NC5 NC 8
V+
7U2BUF634UR3
150
R8
47 R9100
C22.7pf
GND
R4 0R
R5 0R
-V1
IN+3
IN-2 OUT 6
NC5 TRIM 1
TRIM 8
V-
4V
+7U1
OPA602
P2100k
GND
E1
S3
S2
E2
C11.5 pf
R1100
R622
C3
100nf
C5
2.2uf
C6
2.2uf
C9
2.2uf
C10
2.2uf
+V1 +V2
-V1 -V2
PT10
GND
V+
V-
C4
100nf
C8
100nf
C7
100nf
R722
R1222
R1122
Preampli (3A) [U9,U10,U15,U16]
NB: All Résistances values in Ohms /Tol. 1% R1, R8, PT10, No ConnectedA=1 =>G=0 dB
F650K.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:22:16
PreampliFiltre : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA28/03/02
20329
L310uH
L50.68 uH
L410uH
L80.68uH
L1112uH
L60.68uH
L1212uH
L70.68uH
L12.2uH
C2
22nf
C7
10nF
L92.6uH
C3
22nf
C8
10nF
L132.6uH
C4
22nf
C9
10nF
L102.6uH
C5
22nf
C10
10nF
L22.2uH GND
GND
E1 S1
L140.22uH
L150.68uH
L160.68uH
L170.68uH
L180.22uH
GND
GND
E2 S2
Filtre passe bande 650 kHz, [F2, F4]
12
C1
22nf
12
C6
10nF
A= 0.44 =>G=-7 dBCapa. Tol. 2%
F450K.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:21:23
PreampliFiltre : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA28/03/02
20328
L315.01uH
L51uH
L415.01uH
L81uH
L1118.32uH
L61uH
L1218.32uH
L71uH
C1
22nf
C6
10nF
L15.278uH
C2
22nf
C7
10nF
L97.412uH
C3
22nf
C8
10nF
L136.805uH
C4
22nf
C9
10nF
L107.412uH
C5
22nf
C10
10nF
L25.278uH GND
GND
E1 S1
L140.33uH
L150.47uH
L160.47uH
L170.47uH
L180.33uH
GND
GND
E2 S2
Filtre passe bande 450 kHz, [F1, F3]
A= 0.44 =>G=-7 dBCapa. Tol. 2%
F650K.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:22:16
PreampliFiltre : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA28/03/02
20329
L310uH
L50.68 uH
L410uH
L80.68uH
L1112uH
L60.68uH
L1212uH
L70.68uH
L12.2uH
C2
22nf
C7
10nF
L92.6uH
C3
22nf
C8
10nF
L132.6uH
C4
22nf
C9
10nF
L102.6uH
C5
22nf
C10
10nF
L22.2uH GND
GND
E1 S1
L140.22uH
L150.68uH
L160.68uH
L170.68uH
L180.22uH
GND
GND
E2 S2
Filtre passe bande 650 kHz, [F2, F4]
12
C1
22nf
12
C6
10nF
A= 0.44 =>G=-7 dBCapa. Tol. 2%
PreampFiltreBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number PagePHOTODET * *
220uF C1 CRAD0.137 NRSZ/25V NIC DISTRELEC * *
220uF C10 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C11 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C12 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
100nF C13 805 2R serie 10% PHYCOMP FARNELL * *
100nF C14 805 2R serie 10% PHYCOMP FARNELL * *
100nF C15 805 2R serie 10% PHYCOMP FARNELL * *
100nF C16 805 2R serie 10% PHYCOMP FARNELL * *
100nF C17 805 2R serie 10% PHYCOMP FARNELL * *
100nF C18 805 2R serie 10% PHYCOMP FARNELL * *
100nF C19 805 2R serie 10% PHYCOMP FARNELL * *
220uF C2 CRAD0.137 NRSZ/25V NIC DISTRELEC * *
100nF C20 805 2R serie 10% PHYCOMP FARNELL * *
10uF C21 1210 B45196H serie 10% EPCOS FARNELL * *
10uF C22 1210 B45196H serie 10% EPCOS FARNELL * *
10uF C23 1210 B45196H serie 10% EPCOS FARNELL * *
10uF C24 1210 B45196H serie 10% EPCOS FARNELL * *
2.2uf C25 1206 B45196H serie 10% EPCOS FARNELL * *
2.2uf C26 1206 B45196H serie 10% EPCOS FARNELL * *
2.2uf C27 1206 B45196H serie 10% EPCOS FARNELL * *
2.2uf C28 1206 B45196H serie 10% EPCOS FARNELL * *
100nf C29 805 CG serie 5% PHYCOMP FARNELL * *
220uF C3 CRAD0.137 NRSZ/25V NIC DISTRELEC * *
100nf C30 805 CG serie 5% PHYCOMP FARNELL * *
100nf C31 805 CG serie 5% PHYCOMP FARNELL * *
100nf C32 805 CG serie 5% PHYCOMP FARNELL * *
100nf C33 805 CG serie 5% PHYCOMP FARNELL * *
100nf C34 805 CG serie 5% PHYCOMP FARNELL * *
100nf C35 805 CG serie 5% PHYCOMP FARNELL * *
100nf C36 805 CG serie 5% PHYCOMP FARNELL * *
220uF C4 CRAD0.137 NRSZ/25V NIC DISTRELEC * *
220uF C5 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
82nF C53 1812 CG serie 5% PHYCOMP FARNELL * *
82nF C54 1812 CG serie 5% PHYCOMP FARNELL * *
82nF C56 1812 CG serie 5% PHYCOMP FARNELL * *
82nF C57 1812 CG serie 5% PHYCOMP FARNELL * *
82 nF C59 1812 CG serie 5% PHYCOMP FARNELL * *
220uF C6 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
82 nF C60 1812 CG serie 5% PHYCOMP FARNELL * *
82 nF C62 1812 CG serie 5% PHYCOMP FARNELL * *
82 nF C63 1812 CG serie 5% PHYCOMP FARNELL * *
220uF C7 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C8 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C9 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
1N4148 D1 1206 LS4148 VISHAY FARNELL * *
1N4148 D2 1206 LS4148 VISHAY FARNELL * *
BAR43S D3 SOT-23 BAR43S ST FARNELL * *
BAR43S D4 SOT-23 BAR43S ST FARNELL * *
BAR43S D5 SOT-23 BAR43S ST FARNELL * *
BAR43S D6 SOT-23 BAR43S ST FARNELL * *
450kHz F1 FILTREPBE * *
650kHz F2 FILTREPBE * *
450kHz F3 FILTREPBE * *
650kHz F4 FILTREPBE * *
J1 CNVME96 DIN 41612 HARTING DISTRELEC * *
J10 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J11 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J12 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J13 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
1 / 3 MG / 03.05.2003
PreampFiltreBOM
J14 CNVME96 DIN 41612 HARTING DISTRELEC * *
J15 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J16 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J17 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J18 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J19 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J2 MICROMATCH 7-215079-4 TYCO FARNELL * *
J20 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J21 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J22 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J23 PLOT3 537.27 JAEGER AG JAEGER AG * *
J24 PLOT3 537.27 JAEGER AG JAEGER AG * *
J25 PLOT3 537.27 JAEGER AG JAEGER AG * *
J26 PLOT3 537.27 JAEGER AG JAEGER AG * *
J27 PLOT3 537.27 JAEGER AG JAEGER AG * *
J28 PLOT3 537.27 JAEGER AG JAEGER AG * *
J29 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J3 MICROMATCH 7-215079-4 TYCO FARNELL * *
J30 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J31 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J32 PSS00 PSS.00.250.NTME24 LEMO LEMO * *
J33 PSS00 PSS.00.250.NTME24 LEMO LEMO * *
J34 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J35 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J36 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J37 PSS00 PSS.00.250.NTME24 LEMO LEMO * *
J38 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J39 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J4 MICROMATCH 7-215079-4 TYCO FARNELL * *
J40 PSS00 PSS.00.250.NTME24 LEMO LEMO * *
J41 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J42 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J43 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J44 PSS00 * *
J45 PSS00 * *
J46 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J47 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J48 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J49 PSS00 * *
J5 MICROMATCH 7-215079-4 TYCO FARNELL * *
J50 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J51 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J52 PSS00 * *
J53 PLOT22SMA 22SMA-50-0-4 HUBER+SUHNER HUBER+SUHNER * *
J54 PLOT22SMA 22SMA-50-0-4 HUBER+SUHNER HUBER+SUHNER * *
J55 PLOT22SMA 22SMA-50-0-4 HUBER+SUHNER HUBER+SUHNER * *
J56 PLOT22SMA 22SMA-50-0-4 HUBER+SUHNER HUBER+SUHNER * *
J57 PLOT2 537.37 JAEGER AG JAEGER AG * *
J58 PLOT2 537.37 JAEGER AG JAEGER AG * *
J59 PLOT2 537.37 JAEGER AG JAEGER AG * *
J6 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J60 PLOT2 537.37 JAEGER AG JAEGER AG * *
J7 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
82MMCX J8 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J9 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
228 uH L1 SLOT7 Slot7 serie COILCRAFT COILCRAFT * *
228 uH L2 SLOT7 Slot7 serie COILCRAFT COILCRAFT * *
228 uH L3 SLOT7 Slot7 serie COILCRAFT COILCRAFT * *
228 uH L4 SLOT7 Slot7 serie COILCRAFT COILCRAFT * *
5k P1 3266W 3266W BOURNS FARNELL * *
5k P2 3266W 3266W BOURNS FARNELL * *
2 / 3 MG / 03.05.2003
PreampFiltreBOM
PT1 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT2 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT3 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT4 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT5 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT6 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT7 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT8 PLOT3 537.27 JAEGER AG JAEGER AG * *
4.7k R1 1206 CR serie 1% MEGGITT FARNELL * *
0R R10 805 CR serie 1% MEGGITT FARNELL * *
0R R11 805 CR serie 1% MEGGITT FARNELL * *
0R R12 805 CR serie 1% MEGGITT FARNELL * *
0R R13 805 CR serie 1% MEGGITT FARNELL * *
0R R14 805 CR serie 1% MEGGITT FARNELL * *
0R R15 805 CR serie 1% MEGGITT FARNELL * *
0R R16 805 CR serie 1% MEGGITT FARNELL * *
50R R17 1206 CR serie 1% MEGGITT FARNELL * *
50R R18 1206 CR serie 1% MEGGITT FARNELL * *
50R R19 1206 CR serie 1% MEGGITT FARNELL * *
4.7k R2 1206 CR serie 1% MEGGITT FARNELL * *
50R R20 1206 CR serie 1% MEGGITT FARNELL * *
50R R21 1206 CR serie 1% MEGGITT FARNELL * *
50R R22 1206 CR serie 1% MEGGITT FARNELL * *
50R R23 1206 CR serie 1% MEGGITT FARNELL * *
50R R24 1206 CR serie 1% MEGGITT FARNELL * *
4.7k R3 1206 CR serie 1% MEGGITT FARNELL * *
4.7k R4 1206 CR serie 1% MEGGITT FARNELL * *
100R R41 1206 CR serie 1% MEGGITT FARNELL * *
100R R42 1206 CR serie 1% MEGGITT FARNELL * *
100R R43 1206 CR serie 1% MEGGITT FARNELL * *
100R R44 1206 CR serie 1% MEGGITT FARNELL * *
100R R45 1206 CR serie 1% MEGGITT FARNELL * *
100R R46 1206 CR serie 1% MEGGITT FARNELL * *
100R R47 1206 CR serie 1% MEGGITT FARNELL * *
100R R48 1206 CR serie 1% MEGGITT FARNELL * *
100R R5 1206 CR serie 1% MEGGITT FARNELL * *
100R R6 1206 CR serie 1% MEGGITT FARNELL * *
100R R7 1206 CR serie 1% MEGGITT FARNELL * *
100R R8 1206 CR serie 1% MEGGITT FARNELL * *
0R R9 805 CR serie 1% MEGGITT FARNELL * *
T16-6T TV1 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
T16-6T TV2 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
T16-6T TV3 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
T16-6T TV4 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
LM317 U1 LM317 LM317 NS FARNELL * *
Preampli (3A) 450kU10 PREAMP3A * *
Péampli (2) 650kHz U11 PREAMP2 * *
Préampli (2B) 650kHU12 PREAMP2B * *
Ampli (1) 650kHz U13 PREAMP1 * *
Ampli (1) 650kHz U14 PREAMP1 * *
Préampli (3A) 650kHU15 PREAMP3A * *
Preampli (3A) 650kHU16 PREAMP3A * *
LM317 U2 LM317 LM317 NS FARNELL * *
LM337 U3 LM337 LM317 NS FARNELL * *
LM337 U4 LM337 LM317 NS FARNELL * *
Préampli (2) 450kHzU5 PREAMP2 * *
Préampli (2B) 450kHU6 PREAMP2B * *
Ampli (1) 450kHz U7 PREAMP1 * *
Ampli (1) 450kHz U8 PREAMP1 * *
Préampli (3A) 450kHU9 PREAMP3A * *
3 / 3 MG / 03.05.2003
Ampli1PreampFiltreBOM
Part Type Designator Footprint Description Ref. Tol. Manufacturer Supplier Order N Page6.8 pf C1 603 Capa non pol. CG serie 5% PHYCOMP FARNELL * *
2.2uf C10 1206 Capa pol. B45196H 10% EPCOS FARNELL * *
3.9 pf C2 603 Capa non pol. CG serie 5% PHYCOMP FARNELL * *
100nf C3 805 Capa non pol. 2R serie 10% PHYCOMP FARNELL * *
100nf C4 805 Capa non pol. 2R serie 10% PHYCOMP FARNELL * *
2.2uf C5 1206 Capa pol. B45196H 10% EPCOS FARNELL * *
2.2uf C6 1206 Capa pol. B45196H 10% EPCOS FARNELL * *
100nf C7 805 Capa non pol. 2R serie 10% PHYCOMP FARNELL * *
100nf C8 805 Capa non pol. 2R serie 10% PHYCOMP FARNELL * *
2.2uf C9 1206 Capa pol. B45196H 10% EPCOS FARNELL * *
10k P1 3266W Pot. 10trs 3266W BOURNS FARNELL * *
PT10 PLOT3 537.27 JAEGER AG JAEGER AG * *
100 R1 805 Résistance CR serie 1% MEGGITT FARNELL * *
1500 R10 805 Résistance CR serie 1% MEGGITT FARNELL * *
22 R11 1206 Résistance CR serie 1% MEGGITT FARNELL * *
22 R12 1206 Résistance CR serie 1% MEGGITT FARNELL * *
100 R2 805 Résistance CR serie 1% MEGGITT FARNELL * *
150 R3 603 Résistance CR serie 1% MEGGITT FARNELL * *
100 R4 1206 Résistance CR serie 1% MEGGITT FARNELL * *
100 R5 1206 Résistance CR serie 1% MEGGITT FARNELL * *
22 R6 1206 Résistance CR serie 1% MEGGITT FARNELL * *
22 R7 1206 Résistance CR serie 1% MEGGITT FARNELL * *
680 R8 805 Résistance CR serie 1% MEGGITT FARNELL * *
390 R9 805 Résistance CR serie 1% MEGGITT FARNELL * *
THS3001 U1 SO-8 AOP THS3001 TI SPOERLE * *
BUF634U U2 SO-8 Buffer BUF634U TI SPOERLE * *
1 / 1 MG / 03.05.2003
F450KBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page22nf C1 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C10 1206 ECHU1H serie 2% PANASONIC FARNELL * *
22nf C2 1206 ECHU1H serie 2% PANASONIC FARNELL * *
22nf C3 1206 ECHU1H serie 2% PANASONIC FARNELL * *
22nf C4 1206 ECHU1H serie 2% PANASONIC FARNELL * *
22nf C5 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C6 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C7 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C8 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C9 1206 ECHU1H serie 2% PANASONIC FARNELL * *
5.278uH L1 SLOT7 7M3-472 COILCRAFT COILCRAFT * *
7.412uH L10 SLOT7 7M3-682 COILCRAFT COILCRAFT * *
18.32uH L11 SLOT7 7M3-153 COILCRAFT COILCRAFT * *
18.32uH L12 SLOT7 7M3-153 COILCRAFT COILCRAFT * *
6.805uH L13 SLOT7 7M3-682 COILCRAFT COILCRAFT * *
0.33uH L14 SLOT7 7M3-331 COILCRAFT COILCRAFT * *
0.47uH L15 SLOT7 7M3-471 COILCRAFT COILCRAFT * *
0.47uH L16 SLOT7 7M3-471 COILCRAFT COILCRAFT * *
0.47uH L17 SLOT7 7M3-471 COILCRAFT COILCRAFT * *
0.33uH L18 SLOT7 7M3-331 COILCRAFT COILCRAFT * *
5.278uH L2 SLOT7 7M3-472 COILCRAFT COILCRAFT * *
15.01uH L3 SLOT7 7M3-153 COILCRAFT COILCRAFT * *
15.01uH L4 SLOT7 7M3-153 COILCRAFT COILCRAFT * *
1uH L5 SLOT7 7M3-102 COILCRAFT COILCRAFT * *
1uH L6 SLOT7 7M3-102 COILCRAFT COILCRAFT * *
1uH L7 SLOT7 7M3-102 COILCRAFT COILCRAFT * *
1uH L8 SLOT7 7M3-102 COILCRAFT COILCRAFT * *
7.412uH L9 SLOT7 7M3-682 COILCRAFT COILCRAFT * *
1 / 1 MG / 03.05.2003
F650KBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page22nf C1 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C10 1206 ECHU1H serie 2% PANASONIC FARNELL * *
22nf C2 1206 ECHU1H serie 2% PANASONIC FARNELL * *
22nf C3 1206 ECHU1H serie 2% PANASONIC FARNELL * *
22nf C4 1206 ECHU1H serie 2% PANASONIC FARNELL * *
22nf C5 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C6 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C7 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C8 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10nF C9 1206 ECHU1H serie 2% PANASONIC FARNELL * *
2.2uH L1 SLOT7 7M3-222 COILCRAFT COILCRAFT * *
2.6uH L10 SLOT7 7M3-222 COILCRAFT COILCRAFT * *
12uH L11 SLOT7 7M3-153 COILCRAFT COILCRAFT * *
12uH L12 SLOT7 7M3-153 COILCRAFT COILCRAFT * *
2.6uH L13 SLOT7 7M3-222 COILCRAFT COILCRAFT * *
0.22uH L14 SLOT7 7M3-221 COILCRAFT COILCRAFT * *
0.68uH L15 SLOT7 7M3-681 COILCRAFT COILCRAFT * *
0.68uH L16 SLOT7 7M3-681 COILCRAFT COILCRAFT * *
0.68uH L17 SLOT7 7M3-681 COILCRAFT COILCRAFT * *
0.22uH L18 SLOT7 7M3-221 COILCRAFT COILCRAFT * *
2.2uH L2 SLOT7 7M3-222 COILCRAFT COILCRAFT * *
10uH L3 SLOT7 7M3-103 COILCRAFT COILCRAFT * *
10uH L4 SLOT7 7M3-103 COILCRAFT COILCRAFT * *
0.68 uH L5 SLOT7 7M3-681 COILCRAFT COILCRAFT * *
0.68uH L6 SLOT7 7M3-681 COILCRAFT COILCRAFT * *
0.68uH L7 SLOT7 7M3-681 COILCRAFT COILCRAFT * *
0.68uH L8 SLOT7 7M3-681 COILCRAFT COILCRAFT * *
2.6uH L9 SLOT7 7M3-222 COILCRAFT COILCRAFT * *
1 / 1 MG / 03.05.2003
Preampli2PreampFiltreBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page6.8 pf C1 603 CG serie 5% PHYCOMP FARNELL * *
2.2uf C10 1206 B45196H serie 10% EPCOS FARNELL * *
3.9 pf C2 603 CG serie 5% PHYCOMP FARNELL * *
100nf C3 805 2R serie 10% PHYCOMP FARNELL * *
100nf C4 805 2R serie 10% PHYCOMP FARNELL * *
2.2uf C5 1206 B45196H serie 10% EPCOS FARNELL * *
2.2uf C6 1206 B45196H serie 10% EPCOS FARNELL * *
100nf C7 805 2R serie 10% PHYCOMP FARNELL * *
100nf C8 805 2R serie 10% PHYCOMP FARNELL * *
2.2uf C9 1206 B45196H serie 10% EPCOS FARNELL * *
10k P1 3266W 3266W BOURNS FARNELL * *
PT10 PLOT3 537.27 JAEGER AG JAEGER AG 537.27 JAERGER AG
1.8k R1 805 CR serie 1% MEGGITT FARNELL * *
1500 R10 805 CR serie 1% MEGGITT FARNELL * *
22 R11 1206 CR serie 1% MEGGITT FARNELL * *
22 R12 1206 CR serie 1% MEGGITT FARNELL * *
1.5k R2 805 CR serie 1% MEGGITT FARNELL * *
150 R3 603 CR serie 1% MEGGITT FARNELL * *
100 R4 1206 CR serie 1% MEGGITT FARNELL * *
100 R5 1206 CR serie 1% MEGGITT FARNELL * *
22 R6 1206 CR serie 1% MEGGITT FARNELL * *
22 R7 1206 CR serie 1% MEGGITT FARNELL * *
680 R8 805 CR serie 1% MEGGITT FARNELL * *
390 R9 805 CR serie 1% MEGGITT FARNELL * *
THS3001 U1 SO-8 THS3001CD TI SPOERLE * *
BUF634U U2 SO-8 BUF634U TI SPOERLE * *
1 / 1 MG / 03.05.2003
Preampli3PreampFiltreBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page1.5 pf C1 603 CG serie 5% PHYCOMP FARNELL * *
2.2uf C10 1206 B45196H serie 10% EPCOS FARNELL * *
2.7pf C2 603 CG serie 5% PHYCOMP FARNELL * *
100nf C3 805 2R serie 10% PHYCOMP FARNELL * *
100nf C4 805 2R serie 10% PHYCOMP FARNELL * *
2.2uf C5 1206 B45196H serie 10% EPCOS FARNELL * *
2.2uf C6 1206 B45196H serie 10% EPCOS FARNELL * *
100nf C7 805 2R serie 10% PHYCOMP FARNELL * *
100nf C8 805 2R serie 10% PHYCOMP FARNELL * *
2.2uf C9 1206 B45196H serie 10% EPCOS FARNELL * *
100k P2 3266W 3266W BOURNS FARNELL * *
PT10 PLOT3 537.27 JAEGER AG JAEGER AG * *
100 R1 805 CR serie 1% MEGGITT FARNELL * *
22 R11 1206 CR serie 1% MEGGITT FARNELL * *
22 R12 1206 CR serie 1% MEGGITT FARNELL * *
150 R3 603 CR serie 1% MEGGITT FARNELL * *
0R R4 1206 CR serie 1% MEGGITT FARNELL * *
0R R5 1206 CR serie 1% MEGGITT FARNELL * *
22 R6 1206 CR serie 1% MEGGITT FARNELL * *
22 R7 1206 CR serie 1% MEGGITT FARNELL * *
47 R8 805 CR serie 1% MEGGITT FARNELL * *
100 R9 805 CR serie 1% MEGGITT FARNELL * *
OPA602 U1 SO-8 OPA602U TI SPOERLE * *
BUF634U U2 SO-8 BUF634U TI SPOERLE * *
1 / 1 MG / 03.05.2003
Institute of Microtechnology, Neuchâtel OS, 27.3.2003
C
Annex C
Schemtaic circuits of
the Limiter board
Limiter.prj
TITREDessinéDate
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/Sch.N°:Fichier: 1 4Page:
::
:Heure : 22:41:54
Limiter: canal REF + PROBE
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA9/01/03
30122
V+
GND
V-
+5V
GND
-5V
LimiterProbeLimiterProbe.Sch
V+
V-
GND
+5V
GND
-5V
LimiterRefLimiterRef.Sch
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J1
GND
GND
GND
GND
GNDGND
GND
GND
+12V-12V
+5V
-5V
GND
+12V
GND
-12V
+12VGND-12V
J3
J4
J5
+5V
GND
-5V
+12V
GND
-12V
+5V
GND
-5V
+12V
-12V -5V-1
+5V-1
E2 S2
U1
ALIMSTAB
Alimentations
LimiterPROBE.Sch
TITREDessinéDate
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/Sch.N°:Fichier: 3 4Page:
::
:Heure : 22:41:54
Limiteur: canal PROBE
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA9/01/03
30122
PT3R7
0R
GND
GNDGND
GND
V+
V-
E1
E2 S2
S1V+
V-
S3
U9
Préampli (4B) 450kHZ
R3 8.2K1 2
3 4
5 67 8
TV5
TTMO25-1
1 2
3 4
5 67 8
TV6
TTMO25-1 GNDGND
D3 BAR43S
GND
E1
E2 S2
S1V+
V-
S3
U3
Préampli (3A) 450kHZ
J8
GND
GND
V+
V-
C9
100nf
C25
220uF
C10
100nf
C26
220uF
GND
C11
100nf
C27
220uF
C12
100nf
C28
220uF
GND
V+
GND
V- V-
V+
GND
PT4R8
0R
GND
GNDGND
GND
V+
V-
E1
E2 S2
S1V+
V-
S3
U17
Préampli 650kHZ (4B)
R4 8.2K1 2
3 4
5 67 8
TV7
TTMO25-1
1 2
3 4
5 67 8
TV8
TTMO25-1 GNDGND
D4 BAR43S
GND
E1
E2 S2
S1V+
V-
S3
U11
Préampli (3A) 650kHZ
J9
GND
GND
V+
V-GND
MESP 450kHZ
MESP 650kHZ
LimiterIntfLimiterIntf.Sch
R11
220R
J12
GND
J13
GND
E1
E2 S2
S1+5V
-5V
U6
Comparateur à fenêtre
E1
E2S2
S1
+5V
-5V
S3
U14
Convertisseur sinus/carré
GND GND
GNDGND
+5V
+5V
-5V
-5V
R12
220R
E1
E2 S2
S1+5V
-5V
U7
Comparateur à fenêtre
E1
E2S2
S1
+5V
-5V
S3
U15
Convertisseur sinus/carré
GND GND
GNDGND
+5V
+5V
-5V
-5V
C13
100nf
C29
220uF
C14
100nf
C30
220uF
GND
C15
100nf
C31
220uF
C16
100nf
C32
220uF
GND
+5V
GND
-5V -5V
+5V
J14
GND
A=27.7
A=1
A=1
A=27.7
A IN 450 kHz
A IN 650 kHz
D OUT 450 kHz
FC OUT
D OUT 650 kHz
J18 J19
J16 J17
Front Panel Front Panel
LimiterREF.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 2 4Page:
::
:Heure : 22:41:55
Limiteur: canal REF
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA9/01/03
30122
PT1R5
0R
GND
GNDGND
GND
V+
V-
E1
E2 S2
S1V+
V-
S3
U8
Préampli (4B) 450kHZ
R1 8.2K1 2
3 4
5 67 8
TV1
TTMO25-1
1 2
3 4
5 67 8
TV2
TTMO25-1 GNDGND
D1 BAR43S
GND
E1
E2 S2
S1V+
V-
S3
U2
Préampli (3A) 450kHZ
R9
220R
J6
GND
GND
J10
GND
V-
C1
100nf
C17
220uF
C2
100nf
C18
220uF
GND
C3
100nf
C19
220uF
C4
100nf
C20
220uF
GND
V+
GND
V- V-
V+
GND
PT2R6
0R
GND
GNDGND
GND
V+
V-
E1
E2 S2
S1V+
V-
S3
U16
Préampli (4B) 650kHZ
R2 8.2K1 2
3 4
5 67 8
TV3
TTMO25-1
1 2
3 4
5 67 8
TV4
TTMO25-1 GNDGND
D2 BAR43S
GND
E1
E2 S2
S1V+
V-
S3
U10
Préampli (3A) 650kHZ
J7
GND
GND
J11
GND
V+
V-GND
MESR 450kHZ
MESR 650kHZ
LimiterIntfLimiterIntf.Sch
E1
E2 S2
S1+5V
-5V
U4
Comparateur à fenêtre
E1
E2S2
S1
+5V
-5V
S3
U12
Convertisseur sinus/carré
GND GND
GNDGND
+5V
+5V
-5V
-5V
R10
220R
E1
E2 S2
S1+5V
-5V
U5
Comparateur à fenêtre
E1
E2S2
S1
+5V
-5V
S3
U13
Convertisseur sinus/carré
GND GND
GNDGND
+5V
+5V
-5V
-5V
C5
100nf
C21
220uF
C6
100nf
C22
220uF
GND
C7
100nf
C23
220uF
C8
100nf
C24
220uF
GND
+5V
GND
-5V -5V
+5V
V+
J15
GND
A IN 450 kHz
A IN 650 kHz
D OUT 450 kHz
FC OUT
D OUT 650 kHz
A=27.7
A=1
A=1
A=27.7
J22 J23
J20 J21
Front Panel Front Panel
LimiterIntf.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 4 4Page:
::
:Heure : 22:41:55
Limiteur: Interface
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA9/01/03
30122
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J2
MESR 450kHZ
MESP 650kHZ
MESP 450kHZ
MESR 650kHZ
A2
B2
C3
C4
A2
B2
C3
C4
AlimStabLimiter.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:44:08
LIMITER : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA06/02/03
30206
Vin3
AD
J1
+Vout 2U1
LM317
Vin2
AD
J1
-Vout 3
U2
LM337
R34.7k
R44.7k
C810uF
C710uF
C92.2uf
C102.2uf
+5V-1
-5V-1
C6100nF
C5100nF
P15k
C2220uF
C1220uF
C3100nF
C4100nF
GND
D11N4148
D21N4148
+12V
-12V
GND
GND
R1100
R2100
ALIMSTAB, [U1]
CompFLimiter.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:50:15
Limiter : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA04/02/03
30204
-A1
+A2
Q*A 13
V-
3
LE
16
V+
4
QA 14
15
U3A
LT1712
-B8
+B7
Q*B 12
V-
6
LE
9
V+
5
QB 11
10
U3B
LT1712
P10.1k
C3100nF
GND
1
2
3
4
5
&
U4
GND
+5V
+5V-5V
C5100nf
GND
12
U1J503
R139R
GND
C82.2uf
C2100nF
GND
C9
2.2uf
C7
100nF
GND
C1100nF
GND
P20.1k
R239RC4
100nF
GND
+5V
12
U2J503
C6100nF
GND
-5V
E1 S1E2
S2
Comparateur à fenêtre [U4, U5, U6, U7]
CompLimiter.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:49:21
Limiter : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA5/02/03
30205
Convertisseur sinus / carré [U12, U13, U14, U15]
+2
-3
Q* 8
V-
4
LE
5
V+
1
Q 7
6
U1
LT1711
6 1
5 2
4 3
TV1
TT1-6
GNDGND
GNDGND
GND
GND
C1
2.2uf
GND
+5V
C2
2.2uf
GND
-5V
E1
E2
1
2
3
4
5
&
U3
GND
+5V
GND
S1
S2
1
2
3
4
5
1
U2
NOR
GND
+5V
GND
S3C3
100nf
R422
R322
R1100
R2100
C4
100nf
C6
100nf
C5
100nf
Preamp3ALimiter.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 22:48:41
Limiter
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA18/02/02
30225A
+V1 +V2
-V2
S1
V-
4
IN3 OUT 6
BW 1NC2
NC5 NC 8
V+
7U2BUF634UR3
150
R8
47 R9100
C22.7pf
C11.5pf
GND
R4 0R
R5 0R
-V1
IN+3
IN-2 OUT 6
NC5 TRIM 1
TRIM 8
V-
4V
+7U1
OPA602
P2100k
R1100K
GND
E1
S3
S2
E2
Preampli (3A) 450 kHz, 650 kHz [U2, U3, U10, U11]
NB: All Résistances values in Ohms /Tol. 1% R1, R8, PT10, No ConnectedA= 1 =>G=0dB
C4
100nf
C6
10uf
C7
100nf
C9
10uf
C8
100nf
C10
10uf
+V1 +V2
-V1 -V2
PT10
V+
V-
C510uF
C3
100nf
R622
R722
R1122
R1222
GND
Preamp4Limiter.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 0 0Page:
::
:Heure : 22:47:22
LIMITER
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA18/02/02
20226A
V-
4
IN3 OUT 6
BW 1NC2
NC5 NC 8
V+
7U2BUF634U
GND
+V1 +V2
-V1 -V2
C4
100nf
C6
10uf
C7
100nf
C9
10uf
C8
100nf
C10
10uf
+V1 +V2
-V1 -V2
PT10
V-
4
IN-2 IN+3 OUT 6
NC 5NC1
8
V+
7U1THS3001
E1 S1
V+
V-
C510uF
S2
S3
E2
C3
100nf
R622
R722
R1122
R1222
R8 56R10820
R13 68
R3150
C23.9 pf
C16.8 pf
R4100
R5100
GND
NB:Résistances en Ohms.C1, C2, PT10, Non ConnectéA= 27,7 G=28,8 dB
Preampli (4B) [U8,U9,U16,U17]
LimiterBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page100nf C1 805 CG serie 5% PHYCOMP FARNELL * *
100nf C10 805 CG serie 5% PHYCOMP FARNELL * *
100nf C11 805 CG serie 5% PHYCOMP FARNELL * *
100nf C12 805 CG serie 5% PHYCOMP FARNELL * *
100nf C13 805 CG serie 5% PHYCOMP FARNELL * *
100nf C14 805 CG serie 5% PHYCOMP FARNELL * *
100nf C15 805 CG serie 5% PHYCOMP FARNELL * *
100nf C16 805 CG serie 5% PHYCOMP FARNELL * *
220uF C17 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C18 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C19 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
100nf C2 805 CG serie 5% PHYCOMP FARNELL * *
220uF C20 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C21 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C22 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C23 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C24 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C25 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C26 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C27 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C28 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C29 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
100nf C3 805 CG serie 5% PHYCOMP FARNELL * *
220uF C30 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C31 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
220uF C32 CRAD0.137 B45196H serie 10% EPCOS FARNELL * *
100nf C4 805 CG serie 5% PHYCOMP FARNELL * *
100nf C5 805 CG serie 5% PHYCOMP FARNELL * *
100nf C6 805 CG serie 5% PHYCOMP FARNELL * *
100nf C7 805 CG serie 5% PHYCOMP FARNELL * *
100nf C8 805 CG serie 5% PHYCOMP FARNELL * *
100nf C9 805 CG serie 5% PHYCOMP FARNELL * *
BAR43S D1 SOT-23 BAR43S ST FARNELL * *
BAR43S D2 SOT-23 BAR43S ST FARNELL * *
BAR43S D3 SOT-23 BAR43S ST FARNELL * *
BAR43S D4 SOT-23 BAR43S ST FARNELL * *
J1 CNVME96 DIN 41612 HARTING DISTRELEC * *
J10 EPL00250 EPL.00.250.NTN LEMO LEMO * *
81MMCX J11 EPL00250 EPL.00.250.NTN LEMO LEMO * *
81MMCX J12 EPL00250 EPL.00.250.NTN LEMO LEMO * *
J13 EPL00250 EPL.00.250.NTN LEMO LEMO * *
EPL00250 J14 EPL00250 EPL.00.250.NTN LEMO LEMO * *
EPL00250 J15 EPL00250 EPL.00.250.NTN LEMO LEMO * *
J16 25SMA 25SMA-50-2-5 HUBER+SUHNER HUBER+SUHNER * *
J17 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J18 25SMA 25SMA-50-2-5 HUBER+SUHNER HUBER+SUHNER * *
J19 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J2 CNVME96 DIN 41612 HARTING DISTRELEC * *
J20 25SMA 25SMA-50-2-5 HUBER+SUHNER HUBER+SUHNER * *
J21 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J22 25SMA 25SMA-50-2-5 HUBER+SUHNER HUBER+SUHNER * *
J23 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J3 PLOT3 537.27 JAEGER AG JAEGER AG * *
J4 PLOT3 537.27 JAEGER AG JAEGER AG * *
J5 PLOT3 537.27 JAEGER AG JAEGER AG * *
J6 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J7 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J8 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J9 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
PT1 PLOT3 537.27 JAEGER AG JAEGER AG * *
1 / 2 MG / 03.05.2003
LimiterBOM
PT2 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT3 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT4 PLOT3 537.27 JAEGER AG JAEGER AG * *
8.2K R1 1206 CR serie 1% MEGGITT FARNELL * *
220R R10 1206 CR serie 1% MEGGITT FARNELL * *
220R R11 1206 CR serie 1% MEGGITT FARNELL * *
220R R12 1206 CR serie 1% MEGGITT FARNELL * *
8.2K R2 1206 CR serie 1% MEGGITT FARNELL * *
8.2K R3 1206 CR serie 1% MEGGITT FARNELL * *
8.2K R4 1206 CR serie 1% MEGGITT FARNELL * *
0R R5 805 CR serie 1% MEGGITT FARNELL * *
0R R6 805 CR serie 1% MEGGITT FARNELL * *
0R R7 805 CR serie 1% MEGGITT FARNELL * *
0R R8 805 CR serie 1% MEGGITT FARNELL * *
220R R9 1206 CR serie 1% MEGGITT FARNELL * *
TTMO25-1 TV1 MCLA03 TTMO25-1 MINI-CIRCUITS MINI-CIRCUITS * *
TTMO25-1 TV2 MCLA03 TTMO25-1 MINI-CIRCUITS MINI-CIRCUITS * *
TTMO25-1 TV3 MCLA03 TTMO25-1 MINI-CIRCUITS MINI-CIRCUITS * *
TTMO25-1 TV4 MCLA03 TTMO25-1 MINI-CIRCUITS MINI-CIRCUITS * *
TTMO25-1 TV5 MCLA03 TTMO25-1 MINI-CIRCUITS MINI-CIRCUITS * *
TTMO25-1 TV6 MCLA03 TTMO25-1 MINI-CIRCUITS MINI-CIRCUITS * *
TTMO25-1 TV7 MCLA03 TTMO25-1 MINI-CIRCUITS MINI-CIRCUITS * *
TTMO25-1 TV8 MCLA03 TTMO25-1 MINI-CIRCUITS MINI-CIRCUITS * *
ALIMSTAB U1 ALIMSTAB * *
Préampli (3A) 650kHU10 PREAMP3A * *
Préampli (3A) 650kU11 PREAMP3A * *
Convertisseur sinus U12 COMP * *
Convertisseur sinus U13 COMP * *
Convertisseur sinus U14 COMP * *
Convertisseur sinus U15 COMP * *
Préampli (4B) 650kHU16 PREAMP4B * *
Préampli 650kHZ (4U17 PREAMP4B * *
Préampli (3A) 450kHU2 PREAMP3A * *
Préampli (3A) 450kHU3 PREAMP3A * *
Comparateur à fenêU4 COMPF * *
Comparateur à fenêU5 COMPF * *
Comparateur à fenêU6 COMPF * *
Comparateur à fenêU7 COMPF * *
Préampli (4B) 450kHU8 PREAMP4B * *
Préampli (4B) 450kHU9 PREAMP4B * *
2 / 2 MG / 03.05.2003
AlimStabLimiterBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page220uF C1 CRAD0.137 NRSZ/25V NIC DISTRELEC * *
2.2uf C10 1206 B45196H serie 10% EPCOS FARNELL * *
220uF C2 CRAD0.137 NRSZ/25V NIC DISTRELEC * *
100nF C3 805 2R serie 10% PHYCOMP FARNELL * *
100nF C4 805 2R serie 10% PHYCOMP FARNELL * *
100nF C5 805 2R serie 10% PHYCOMP FARNELL * *
100nF C6 805 2R serie 10% PHYCOMP FARNELL * *
10uF C7 1210 B45196H serie 10% EPCOS FARNELL * *
10uF C8 1210 B45196H serie 10% EPCOS FARNELL * *
2.2uf C9 1206 B45196H serie 10% EPCOS FARNELL * *
1N4148 D1 MLL34 LS4148 VISHAY FARNELL * *
1N4148 D2 MLL34 LS4148 VISHAY FARNELL * *
5k P1 3266W 3266W BOURNS FARNELL * *
100 R1 1206 CR serie 1% MEGGITT FARNELL * *
100 R2 1206 CR serie 1% MEGGITT FARNELL * *
4.7k R3 1206 CR serie 1% MEGGITT FARNELL * *
4.7k R4 1206 CR serie 1% MEGGITT FARNELL * *
LM317 U1 LM317 LM317 NS FARNELL * *
LM337 U2 LM337 LM317 NS FARNELL * *
1 / 1 MG / 03.05.2003
CompFLimiterBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page100nF C1 805 2R serie 10% PHYCOMP FARNELL * *
100nF C2 805 2R serie 10% PHYCOMP FARNELL * *
100nF C3 805 2R serie 10% PHYCOMP FARNELL * *
100nF C4 805 2R serie 10% PHYCOMP FARNELL * *
100nf C5 805 2R serie 10% PHYCOMP FARNELL * *
100nF C6 805 2R serie 10% PHYCOMP FARNELL * *
100nF C7 805 2R serie 10% PHYCOMP FARNELL * *
2.2uf C8 1206 B45196H serie 10% EPCOS FARNELL * *
2.2uf C9 1206 B45196H serie 10% EPCOS FARNELL * *
0.1k P1 3266W 3266W BOURNS FARNELL * *
0.1k P2 3266W 3266W BOURNS FARNELL * *
39R R1 402 CR serie 1% MEGGITT FARNELL * *
39R R2 402 CR serie 1% MEGGITT FARNELL * *
J503 U1 TO-92 J503 VISHAY FARNELL * *
J503 U2 TO-92 J503 VISHAY FARNELL * *
LT1712 U3 SOT519-1 LT1712IGN LINEAR TECHNOLOGYLINEAR TECHNOLOGY* *
U4 SOT-23-5 74HCT1G00GW PHILIPS FARNELL * *
1 / 1 MG / 03.05.2003
CompLimiterBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page2.2uf C1 1206 B45196H serie 10% EPCOS FARNELL * *
2.2uf C2 1206 B45196H serie 10% EPCOS FARNELL * *
100nf C3 805 2R serie 10% PHYCOMP FARNELL * *
100nf C4 805 2R serie 10% PHYCOMP FARNELL * *
100nf C5 805 2R serie 10% PHYCOMP FARNELL * *
100nf C6 805 2R serie 10% PHYCOMP FARNELL * *
100 R1 1206 CR serie 1% MEGGITT FARNELL * *
100 R2 1206 CR serie 1% MEGGITT FARNELL * *
22 R3 1206 CR serie 1% MEGGITT FARNELL * *
22 R4 1206 CR serie 1% MEGGITT FARNELL * *
TT1-6 TV1 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
LT1711 U1 SO-RM8 LT1711IM LINEAR LINEAR * *
NOR U2 SOT-23-5 NC7SZ02M5 FAIRCHILD FARNELL * *
U3 SOT-23-5 NC7SZ08M5 FAIRCHILD FARNELL * *
1 / 1 MG / 03.05.2003
Preamp3ALimiterBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page1.5pf C1 603 CG serie 5% PHYCOMP FARNELL * *
10uf C10 1210 B45196H serie 10% EPCOS FARNELL * *
2.7pf C2 603 CG serie 5% PHYCOMP FARNELL * *
100nf C3 805 2R serie 10% PHYCOMP FARNELL * *
100nf C4 805 2R serie 10% PHYCOMP FARNELL * *
10uF C5 1210 B45196H serie 10% EPCOS FARNELL * *
10uf C6 1210 B45196H serie 10% EPCOS FARNELL * *
100nf C7 805 2R serie 10% PHYCOMP FARNELL * *
100nf C8 805 2R serie 10% PHYCOMP FARNELL * *
10uf C9 1210 B45196H serie 10% EPCOS FARNELL * *
100k P2 3266W 3266W BOURNS FARNELL * *
PT10 PLOT3 537.27 JAEGER AG JAEGER AG * *
100K R1 805 CR serie 1% MEGGITT FARNELL * *
22 R11 1206 CR serie 1% MEGGITT FARNELL * *
22 R12 1206 CR serie 1% MEGGITT FARNELL * *
150 R3 603 CR serie 1% MEGGITT FARNELL * *
0R R4 1206 CR serie 1% MEGGITT FARNELL * *
0R R5 1206 CR serie 1% MEGGITT FARNELL * *
22 R6 1206 CR serie 1% MEGGITT FARNELL * *
22 R7 1206 CR serie 1% MEGGITT FARNELL * *
47 R8 805 CR serie 1% MEGGITT FARNELL * *
100 R9 805 CR serie 1% MEGGITT FARNELL * *
OPA602 U1 SO-8 OPA602U TI SPOERLE * *
BUF634U U2 SO-8 BUF634U TI SPOERLE * *
1 / 1 MG / 03.05.2003
Preamp4LimiterBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page6.8 pf C1 603 CG serie 5% PHYCOMP FARNELL * *
10uf C10 1210 B45196H serie 10% EPCOS FARNELL * *
3.9 pf C2 603 CG serie 5% PHYCOMP FARNELL * *
100nf C3 805 2R serie 10% PHYCOMP FARNELL * *
100nf C4 805 2R serie 10% PHYCOMP FARNELL * *
10uF C5 1210 B45196H serie 10% EPCOS FARNELL * *
10uf C6 1210 B45196H serie 10% EPCOS FARNELL * *
100nf C7 805 2R serie 10% PHYCOMP FARNELL * *
100nf C8 805 2R serie 10% PHYCOMP FARNELL * *
10uf C9 1210 B45196H serie 10% EPCOS FARNELL * *
PT10 PLOT3 537.27 JAEGER AG JAEGER AG * *
820 R10 805 CR serie 1% MEGGITT FARNELL * *
22 R11 1206 CR serie 1% MEGGITT FARNELL * *
22 R12 1206 CR serie 1% MEGGITT FARNELL * *
68 R13 805 CR serie 1% MEGGITT FARNELL * *
150 R3 603 CR serie 1% MEGGITT FARNELL * *
100 R4 1206 CR serie 1% MEGGITT FARNELL * *
100 R5 1206 CR serie 1% MEGGITT FARNELL * *
22 R6 1206 CR serie 1% MEGGITT FARNELL * *
22 R7 1206 CR serie 1% MEGGITT FARNELL * *
56 R8 805 CR serie 1% MEGGITT FARNELL * *
THS3001 U1 SO-8 THS3001CD TI SPOERLE * *
BUF634U U2 SO-8 BUF634U TI SPOERLE * *
1 / 1 MG / 03.05.2003
Institute of Microtechnology, Neuchâtel OS, 27.3.2003
D
Annex D
Schematic circuits of
the Mixer board
Mixer.prj
TITREDessinéDate
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:Heure : 23:05:46
Mixer: canal REF + PROBE
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA31/01/03
30131
V+
GND
V-
+5V
GND
-5V
MixerProbeRefMixerProbeRef.Sch
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J1
GND
GND
GND
GND
GNDGND
GND
GND
+12V-12V
+5V
-5V
+12V
GND
-12V
J2
J3
J4
+5V
GND
-5V
+12V
-12V -5V-1
+5V-1
E2 S2
U1
ALIMSTAB
C5
100nf
C21
47uF
C13
100nf
C7
100nf
C14
100nf
C1
100nf
C6
100nf
GND
C2
100nf
C8
100nf
GND
C23
47uF
C17
47uF
C18
47uF
C24
47uF
C22
47uF
C29
47uF
C30
47uF
C3
100nf
C19
47uF
C11
100nf
C4
100nf
C12
100nf
C20
47uF
C27
47uF
C28
47uF
C9
100nf
C25
47uF
C15
100nf
C10
100nf
C16
100nf
C26
47uF
C31
47uF
C32
47uF
C33
100nf
C37
47uF
C34
100nf
C35
100nf
C36
100nf
C39
47uF
C38
47uF
C40
47uF
Alimentations
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J11
MixerProbeRef.Sch
TITREDessinéDate
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/Sch.N°:Fichier: 2 2Page:
::
:Heure : 23:05:47
Mixer: canal REF + PROBE
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA31/01/03
30131
PT1R1
0R
GNDGND
V+
V-
E1
E2 S2
S1V+
V-
S3
U3
Préampli (2)
J9
GND
IF 4
GN
D2
IF 3
GN
D6
LO8
GN
D5
RF1
GN
D7
U8
SRA-6
E1
E2 S2
S1V+
V-
S3
U2
Préampli (1) 450kHZ
J56 1
5 2
4 3
TV1
TT1-6
GND GNDGND
E1
E2 S2
S1V+
V-
S3
U10
Préampli (2) 650kHZ
6 1
5 2
4 3
TV2
TT1-6
GND GNDGND
V+
V-
V+
V-
GNDGND
GND
PT3R3
0R
GNDGND
V+
V-
E1
E2 S2
S1V+
V-
S3
U6
Préampli (2)IF 4
GN
D2
IF 3
GN
D6
LO8
GN
D5
RF1
GN
D7
U9
SRA-6
E1
E2 S2
S1V+
V-
S3
U5
Préampli (1) 450kHZ
6 1
5 2
4 3
TV3
TT1-6
GND GNDGND
E1
E2 S2
S1V+
V-
S3
U11
Préampli (2) 650kHZ
6 1
5 2
4 3
TV4
TT1-6
GND GNDGND
V+
V-
V+
V-
GNDGND
GND
GND
GND
V+
GND
V- V-
V+
GND
GND
GND
GND
E1 S1
E2 S2
F1
200 kHz
E1
E2 S2
S1V+
V-
S3
U4
Préampli (2B)
E1
E2S2
S1
+5V
-5V
S3
U12
Convertisseur sinus/carré
GND GND
+5V
-5V
PT2R2
0R
V+
V-GND GNDGND
J10
GND
E1 S1
E2 S2
F2
200 kHz
E1
E2 S2
S1V+
V-
S3
U7
Préampli (2B)
E1
E2S2
S1
+5V
-5V
S3
U13
Convertisseur sinus/carré
GND GND
+5V
-5V
PT4R4
0R
V+
V-GND GNDGND
GND
GND
+5V
GND
-5V -5V
+5V
GND
GND
A=Adj
A=Adj
A=Adj
A=Adj
A=4
A=4
A=Adj
A=Adj
D IN 450 kHz
D IN 450 kHz
D IN 650 kHz
D IN 650 kHz
D OUT 200 kHz
D OUT 200 kHz
J23J22
J19J18
J6
J7
J8
J12 J13
J14 J16
J15 J17
J20 J21
Front Panel Front Panel
AlimStabMixer.Sch
TITREDessinéDate
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/Sch.N°:Fichier: 1 1Page:
::
:Heure : 23:07:55
MIXER : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA06/02/03
30206
Vin3
AD
J1
+Vout 2U1
LM317
Vin2
AD
J1
-Vout 3
U2
LM337
R34.7k
R44.7k
C810uF
C710uF
C92.2uf
C102.2uf
+5V-1
-5V-1
C6100nF
C5100nF
P15k
C2220uF
C1220uF
C3100nF
C4100nF
GND
D11N4148
D21N4148
+12V
-12V
GND
GND
R1100
R2100
ALIMSTAB, [U1]
CompMixer.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 23:10:27
Mixer : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA5/02/03
30205
Convertisseur sinus / carré [U12, U13]
+2
-3
Q* 8
V-
4
LE
5
V+
1
Q 7
6
U1
LT1711
6 1
5 2
4 3
TV1
TT1-6
GNDGND
GNDGND
GND
GND
C1
2.2uf
GND
+5V
C2
2.2uf
GND
-5V
E1
E2
1
2
3
4
5
&
U3
GND
+5V
GND
S1
S2
1
2
3
4
5
1
U2
NOR
GND
+5V
GND
S3C3
100nf
R422
R322
21
R1100
21
R2100
C4
100nf
C6
100nf
C5
100nf
F200K.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 23:11:18
Mixer : Schéma structurel
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA28/03/02
20328
L333uH
L53.3uH
L433uH
L83.3uH
L1139uH
L63.3uH
L1239uH
L73.3uH
C1
68nf
C6
4.7nF
L110uH
C2
68nf
C7
4.7nF
L915uH
C3
68nf
C8
4.7nF
L1315uH
C4
68nf
C9
4.7nF
L1015uH
C5
68nf
C10
4.7nF
L210uH GND
GND
E1 S1
L140.68uH
L151uH
L161uH
L171uH
L180.68uH
GND
GND
E2 S2
Filtre 200 kHz (F1, F2)
A=0.44 G=>-7dB
Ampli1_2Mixer.Sch
TITREDessinéDate
Modifié 3-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 23:09:01
Mixer: Schéma structurel canal REF+ canal PROBE
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIA18/02/02
20218A
R622
C3
100nf
C5
2.2uf
C6
2.2uf
C9
2.2uf
C10
2.2uf
+V1 +V2
-V1 -V2
PT10
GND
V+
V-
R2100
GND
V-
4
IN3 OUT 6
BW 1NC2
NC5 NC 8
V+
7U2BUF634UR3
150
R8
680
R101500
C23.9 pf
C16.8 pf
GND
R4100
R9
390
+V1 +V2
-V1 -V2
P110k
V-
4
IN-2 IN+3 OUT 6
NC 5NC1
8
V+
7U1THS3001
E1 S1
E2
S2
S3
C4
100nf
C8
100nf
C7
100nf
R1100 R5
100
R722
R1222
R1122
Préampli (1), Préampli (2),(2B), [U2,U3,U4,U5,U6,U7,U10,U11]
NB: All Résistances values in Ohms /Tol. 1% C2, C1, PT10, No ConnectedA= 4 =>G=12 dB
MixerBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page100nf C1 805 2R serie 10% PHYCOMP FARNELL * *
100nf C10 805 2R serie 10% PHYCOMP FARNELL * *
100nf C11 805 2R serie 10% PHYCOMP FARNELL * *
100nf C12 805 2R serie 10% PHYCOMP FARNELL * *
100nf C13 805 2R serie 10% PHYCOMP FARNELL * *
100nf C14 805 2R serie 10% PHYCOMP FARNELL * *
100nf C15 805 2R serie 10% PHYCOMP FARNELL * *
100nf C16 805 2R serie 10% PHYCOMP FARNELL * *
47uF C17 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C18 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C19 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
100nf C2 805 2R serie 10% PHYCOMP FARNELL * *
47uF C20 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C21 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C22 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C23 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C24 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C25 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C26 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C27 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C28 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C29 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
100nf C3 805 2R serie 10% PHYCOMP FARNELL * *
47uF C30 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C31 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C32 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
100nf C33 805 2R serie 10% PHYCOMP FARNELL * *
100nf C34 805 2R serie 10% PHYCOMP FARNELL * *
100nf C35 805 2R serie 10% PHYCOMP FARNELL * *
100nf C36 805 2R serie 10% PHYCOMP FARNELL * *
47uF C37 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C38 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
47uF C39 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
100nf C4 805 2R serie 10% PHYCOMP FARNELL * *
47uF C40 CRAD0.078 ZL/25V serie RUBICON DISTRELEC * *
100nf C5 805 2R serie 10% PHYCOMP FARNELL * *
100nf C6 805 2R serie 10% PHYCOMP FARNELL * *
100nf C7 805 2R serie 10% PHYCOMP FARNELL * *
100nf C8 805 2R serie 10% PHYCOMP FARNELL * *
100nf C9 805 2R serie 10% PHYCOMP FARNELL * *
200 kHz F1 FILTREPBE * *
200 kHz F2 FILTREPBE * *
J1 CNVME96 DIN 41612 HARTING DISTRELEC * *
82MMCX J10 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
J11 CNVME96 DIN 41612 HARTING DISTRELEC * *
J12 25SMA 25SMA-50-2-5 HUBER+SUHNER HUBER+SUHNER * *
J13 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J14 25SMA 25SMA-50-2-5 HUBER+SUHNER HUBER+SUHNER * *
J15 25SMA 25SMA-50-2-5 HUBER+SUHNER HUBER+SUHNER * *
J16 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J17 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J18 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J19 PSS00 PSS.00.250.NTME24 LEMO LEMO * *
J2 PLOT3 537.27 JAEGER AG JAEGER AG * *
J20 25SMA 25SMA-50-2-5 HUBER+SUHNER HUBER+SUHNER * *
J21 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J22 16MMCX 16MMCX-50-1-1 HUBER+SUHNER HUBER+SUHNER * *
J23 PSS00 PSS.00.250.NTME24 LEMO LEMO * *
J3 PLOT3 537.27 JAEGER AG JAEGER AG * *
J4 PLOT3 537.27 JAEGER AG JAEGER AG * *
1 / 2 MG / 03.05.2003
MixerBOM
82MMCX J5 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
82MMCX J6 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
82MMCX J7 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
82MMCX J8 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
82MMCX J9 82MMCX 82MMCX-50-0-01 HUBER+SUHNER HUBER+SUHNER * *
PT1 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT2 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT3 PLOT3 537.27 JAEGER AG JAEGER AG * *
PT4 PLOT3 537.27 JAEGER AG JAEGER AG * *
0R R1 805 CR serie 1% MEGGITT FARNELL * *
0R R2 805 CR serie 1% MEGGITT FARNELL * *
0R R3 805 CR serie 1% MEGGITT FARNELL * *
0R R4 805 CR serie 1% MEGGITT FARNELL * *
TT1-6 TV1 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
TT1-6 TV2 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
TT1-6 TV3 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
TT1-6 TV4 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
ALIMSTAB U1 ALIMSTAB3 * *
Préampli (2) 650kHZU10 PREAMP2 * *
Préampli (2) 650kHZU11 PREAMP2 * *
Convertisseur sinus U12 COMPB * *
Convertisseur sinus U13 COMPB * *
Préampli (1) 450kHZU2 PREAMP1 * *
Préampli (2) U3 PREAMP2 * *
Préampli (2B) U4 PREAMP2B * *
Préampli (1) 450kHZU5 PREAMP1 * *
Préampli (2) U6 PREAMP2 * *
Préampli (2B) U7 PREAMP2B * *
SRA-6 U8 A01 SRA-6 MINI-CIRCUITS MINI-CIRCUITS * *
SRA-6 U9 A01 SRA-6 MINI-CIRCUITS MINI-CIRCUITS * *
2 / 2 MG / 03.05.2003
AlimStabMixerBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page220uF C1 CRAD0.137 NRSZ/25V NIC DISTRELEC * *
2.2uf C10 1206 B45196H serie 10% EPCOS FARNELL * *
220uF C2 CRAD0.137 NRSZ/25V NIC DISTRELEC * *
100nF C3 805 2R serie 10% PHYCOMP FARNELL * *
100nF C4 805 2R serie 10% PHYCOMP FARNELL * *
100nF C5 805 2R serie 10% PHYCOMP FARNELL * *
100nF C6 805 2R serie 10% PHYCOMP FARNELL * *
10uF C7 1210 B45196H serie 10% EPCOS FARNELL * *
10uF C8 1210 B45196H serie 10% EPCOS FARNELL * *
2.2uf C9 1206 B45196H serie 10% EPCOS FARNELL * *
1N4148 D1 MLL34 LS4148 VISHAY FARNELL * *
1N4148 D2 MLL34 LS4148 VISHAY FARNELL * *
5k P1 3266W 3266W BOURNS FARNELL * *
100 R1 1206 CR serie 1% MEGGITT FARNELL * *
100 R2 1206 CR serie 1% MEGGITT FARNELL * *
4.7k R3 1206 CR serie 1% MEGGITT FARNELL * *
4.7k R4 1206 CR serie 1% MEGGITT FARNELL * *
LM317 U1 LM317 LM317 NS FARNELL * *
LM337 U2 LM337 LM317 NS FARNELL * *
1 / 1 MG / 03.05.2003
Ampli1_2MixerBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Oreder Number Page6.8 pf C1 603 CG serie 5% PHYCOMP FARNELL * *
2.2uf C10 1206 B45196H serie 10% EPCOS FARNELL * *
3.9 pf C2 603 CG serie 5% PHYCOMP FARNELL * *
100nf C3 805 2R serie 10% PHYCOMP FARNELL * *
100nf C4 805 2R serie 10% PHYCOMP FARNELL * *
2.2uf C5 1206 B45196H serie 10% EPCOS FARNELL * *
2.2uf C6 1206 B45196H serie 10% EPCOS FARNELL * *
100nf C7 805 2R serie 10% PHYCOMP FARNELL * *
100nf C8 805 2R serie 10% PHYCOMP FARNELL * *
2.2uf C9 1206 B45196H serie 10% EPCOS FARNELL * *
10k P1 3266W 3266W BOURNS FARNELL * *
PT10 PLOT3 537.27 JAEGER AG JAEGER AG * *
100 R1 805 CR serie 1% MEGGITT FARNELL * *
1500 R10 805 CR serie 1% MEGGITT FARNELL * *
22 R11 1206 CR serie 1% MEGGITT FARNELL * *
22 R12 1206 CR serie 1% MEGGITT FARNELL * *
100 R2 805 CR serie 1% MEGGITT FARNELL * *
150 R3 603 CR serie 1% MEGGITT FARNELL * *
100 R4 1206 CR serie 1% MEGGITT FARNELL * *
100 R5 1206 CR serie 1% MEGGITT FARNELL * *
22 R6 1206 CR serie 1% MEGGITT FARNELL * *
22 R7 1206 CR serie 1% MEGGITT FARNELL * *
680 R8 805 CR serie 1% MEGGITT FARNELL * *
390 R9 805 CR serie 1% MEGGITT FARNELL * *
THS3001 U1 SO-8 THS3001CD TI SPOERLE * *
BUF634U U2 SO-8 BUF634U TI SPOERLE * *
1 / 1 MG / 03.05.2003
CompMixerBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page2.2uf C1 1206 B45196H serie 10% EPCOS FARNELL * *
2.2uf C2 1206 B45196H serie 10% EPCOS FARNELL * *
100nf C3 805 2R serie 10% PHYCOMP FARNELL * *
100nf C4 805 2R serie 10% PHYCOMP FARNELL * *
100nf C5 805 2R serie 10% PHYCOMP FARNELL * *
100nf C6 805 2R serie 10% PHYCOMP FARNELL * *
100 R1 1206 CR serie 1% MEGGITT FARNELL * *
100 R2 1206 CR serie 1% MEGGITT FARNELL * *
22 R3 1206 CR serie 1% MEGGITT FARNELL * *
22 R4 1206 CR serie 1% MEGGITT FARNELL * *
TT1-6 TV1 X65 TT1-6 MINI-CIRCUITS MINI-CIRCUITS * *
LT1711 U1 SO-RM8 LT1711IM LINEAR LINEAR * *
NOR U2 SOT-23-5 NC7SZ02M5 FAIRCHILD FARNELL * *
U3 SOT-23-5 NC7SZ08M5 FAIRCHILD FARNELL * *
1 / 1 MG / 03.05.2003
F200KBOM
Part Type Designator Footprint Ref. Tol. Manufacturer Supplier Order Number Page68nf C1 1206 ECHU1H serie 2% PANASONIC FARNELL * *
4.7nF C10 1206 ECHU1H serie 2% PANASONIC FARNELL * *
68nf C2 1206 ECHU1H serie 2% PANASONIC FARNELL * *
68nf C3 1206 ECHU1H serie 2% PANASONIC FARNELL * *
68nf C4 1206 ECHU1H serie 2% PANASONIC FARNELL * *
68nf C5 1206 ECHU1H serie 2% PANASONIC FARNELL * *
4.7nF C6 1206 ECHU1H serie 2% PANASONIC FARNELL * *
4.7nF C7 1206 ECHU1H serie 2% PANASONIC FARNELL * *
4.7nF C8 1206 ECHU1H serie 2% PANASONIC FARNELL * *
4.7nF C9 1206 ECHU1H serie 2% PANASONIC FARNELL * *
10uH L1 SLOT7 7M3-103 COILCRAFT COILCRAFT * *
15uH L10 SLOT7 7M3-153 COILCRAFT COILCRAFT * *
39uH L11 SLOT7 7M3-393 COILCRAFT COILCRAFT * *
39uH L12 SLOT7 7M3-393 COILCRAFT COILCRAFT * *
15uH L13 SLOT7 7M3-153 COILCRAFT COILCRAFT * *
0.68uH L14 SLOT7 7M3-681 COILCRAFT COILCRAFT * *
1uH L15 SLOT7 7M3-102 COILCRAFT COILCRAFT * *
1uH L16 SLOT7 7M3-102 COILCRAFT COILCRAFT * *
1uH L17 SLOT7 7M3-102 COILCRAFT COILCRAFT * *
0.68uH L18 SLOT7 7M3-681 COILCRAFT COILCRAFT * *
10uH L2 SLOT7 7M3-103 COILCRAFT COILCRAFT * *
33uH L3 SLOT7 7M3-333 COILCRAFT COILCRAFT * *
33uH L4 SLOT7 7M3-333 COILCRAFT COILCRAFT * *
3.3uH L5 SLOT7 7M3-332 COILCRAFT COILCRAFT * *
3.3uH L6 SLOT7 7M3-332 COILCRAFT COILCRAFT * *
3.3uH L7 SLOT7 7M3-332 COILCRAFT COILCRAFT * *
3.3uH L8 SLOT7 7M3-332 COILCRAFT COILCRAFT * *
15uH L9 SLOT7 7M3-153 COILCRAFT COILCRAFT * *
1 / 1 MG / 03.05.2003
Institute of Microtechnology, Neuchâtel OS, 27.3.2003
E
Annex E
Global sketch of the
Digital Phasemeter board
DigaitalPM.Sch
TITRE
DessinéDate
Modifié 8-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 15:11:00
DIGITAL PM
Rue A.-L. Breguet 22000 Neuchâtel
GROCCIAA
30327
PROBE
REF
200 MHz
REF Q
200 MHz
200K PROBE DETECTED
PROBE
REF
CLK2
PHASE SHIFTER
PROBE
REF
200 MHz
REF Q
PM OVERFLOW
REQ
INST.PM
A0
A1
CLK2
TIM
REQ
OE1
PK
CN
T
ADDER
200 MHz
LOCKED
PLL[D0...D31]
D OUT 200 kHz
D OUT 200 kHz
DC REF 450 K
REF 1.8V ADRD
ADCSADWRMAX152
DC REF 650 K
REF 1.8V ADRDADWRADCS
MAX152
DC PROBE 450 K
REF 1.8V ADRDADWRADCS
MAX152
DC PROBE 650 K
REF 1.8V ADRDADWRADCS
MAX152
MESR 450K
MESR 650K
MESP 450K
MESP 650K
DC REF 450K
DC PROBE 450K
DC PROBE 650K
DC REF 650K
MESR 450KPIC12508A
MESR 650KPIC12508A
MESP 450KPIC12508A
MESP 650KPIC12508A
[D0...D7]
[D0...D7]
[D0...D7]
[D0...D7]
DATA BUS
OE3
LOAD
2 x SN74LVTH16374STAT LOAD
[D0...D7]
[D0...D7]
[D0...D7]
[D0...D7] 450K REF DETECTED
650K REF DETECTED
450K PROBE DETECTED
450K PROBE DETECTED
RESET DETECTED
TRIG DETECTED
FC OVERFLOW
PM OVERFLOW
2OOK PROBE DETECTED
PLL LOCKED
DATA BUS
OE4
LOAD
PKCNT
2 x SN74LVTH16374STAT LOAD
PLL LCK
200KPD
PMOV
PMOV
200KPD
PLL LCK
CLK2
TIM
OE1OE2OE3OE4
A0A1
STROBE
RESET
ADCS
TRIG DET
ADWR
ADRD
LOAD
RESET DET
PKCNT
ADRESSER
Status 1 or Status 2 [D0...D31]
Status 2 [D0...D31]
CLK2
TIM
A0A1
A0
A1
OE1
PROBE 450
REF 450
CLK2
OE2
FC OVERFLOW
ERROR COMPENSATION
TRIG
RESET
FCOV
FCOV
CLK2
OE2
TRIG DET
RESET DET
V REF 1.8V
MAX6100
Status 1 [D0...D31]
AM26C31
9 X Differential line driver
FR
ON
T P
AN
EL
CO
NE
CT
OR
[D0...D31]
[DO...D31]
[DO...D31]
STROBELIM
ITE
RP
RE
AM
PF
ILT
ER
FC IN
FC IN
FC IN PROBE
FC IN REF
MIX
ER PROBE
REF
TIM
OE4
Dat
a B
us [D
0+...
D31
+]
PCB INTERFACE
CLK2
ADCSADWRADRD
ADCSADWRADRD
ADCSADWRADRD
ADCSADWRADRD
Dat
a B
us [D
0-...
D31
-]
ST
RO
BE
+S
TR
OB
E-
OE3
J66
TO PMC BOARD
[D0...D3]
[D0...D3]
Institute of Microtechnology, Neuchâtel OS, 27.3.2003
F
Annex F
Backplane connections of
the phasemeter boards
FARPhasemeter.Sch
TITREDessinéDate
Modifié
GROCCIA
8-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 15:09:43
26/02/03Phase mètre : Câblage face arrière
Rue A.-L. Breguet 22000 Neuchâtel
Error : logoimtFn_b_640.bmp file not found.
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
Jx
DIN96
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J2 (P2)
DIGITAL PM
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J11
Mixer
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J2 (P2)
Limiter
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J14 (P2)
PreampFiltre
ME
SP 4
50K
HZ
ME
SP 6
50K
HZ
ME
SR 4
50K
HZ
ME
SR 6
50K
HZ
DC
RE
F 45
0K
DC
RE
F 65
0K
DC
PR
OB
E 4
50K
DC
PR
OB
E 6
50K
123456789
10111213141516171819202122232425262728293031323334353637383940
41424344454647484950515253545556575859606162636465666768697071727374757677787980
J1
DIN80
PCB Interface
ME
SP 4
50K
HZ
ME
SP 6
50K
HZ
ME
SR 4
50K
HZ
ME
SR 6
50K
HZ
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J1A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J1A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J1A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
J1
A1A2A3A4A5A6A7A8A9
A10A11A12A13A14A15A16A17A18A19A20A21A22A23A24A25A26A27A28A29A30A31A32
B1B2B3B4B5B6B7B8B9B10B11B12B13B14B15B16B17B18B19B20B21B22B23B24B25B26B27B28B29B30B31B32
C1C2C3C4C5C6C7C8C9C10C11C12C13C14C15C16C17C18C19C20C21C22C23C24C25C26C27C28C29C30C31C32
Jx
DIN96
DC
RE
F 45
0KD
C R
EF
650K
DC
PR
OB
E 4
50K
DC
PR
OB
E 6
50K
PMC80
-12V +12V
GND
-12V +12V
GND
-12V +12V
GND
-12V +12V
GND
-12V +12V
GND
AL
IM S
TA
B
GND
+12V
-12V
TRIG
RESET
RESETTRIG
Lemo
Lemo
CABLE D31+
STROBE +STROBE -
CABLE D0+CABLE D0-CABLE D1+CABLE D1-CABLE D2+CABLE D2-CABLE D3+CABLE D3-CABLE D4+CABLE D4-CABLE D5+CABLE D5-CABLE D6+CABLE D6-CABLE D7+CABLE D7-CABLE D8+CABLE D8-CABLE D9+CABLE D9-CABLE D10+CABLE D10-CABLE D11+CABLE D11-
CABLE D12+CABLE D12-CABLE D13+CABLE D13-CABLE D14+CABLE D14-CABLE D15+CABLE D15-CABLE D16+CABLE D16-CABLE D17+CABLE D17-CABLE D18+CABLE D18-CABLE D19+CABLE D19-CABLE D20+CABLE D20-CABLE D21+CABLE D21-CABLE D22+CABLE D22-CABLE D23+CABLE D23-CABLE D24+CABLE D24-CABLE D25+CABLE D25-CABLE D26+CABLE D26-CABLE D27+CABLE D27-CABLE D28+CABLE D28-CABLE D29+CABLE D29-CABLE D30+CABLE D30-
CABLE D31-
Institute of Microtechnology, Neuchâtel OS, 27.3.2003
G
Annex G
Front panel connections of
the phasemeter boards
SchCablage.Sch
TITREDessinéDate
Modifié
GROCCIA
5-May-2003
/Sch.N°:Fichier: 1 1Page:
::
:Heure : 13:07:32
4/05/03Phase mètre : Schéma de câblage
Rue A.-L. Breguet 22000 Neuchâtel
PhotodetectorINOPT1
INEL1
DET1 OUT
OUT 450 kHz D OUT 450 kHz
DC REF 450K
1.2 V/u W
InGaAs
INOPT2
INEL2
DET2 OUT
OUT 650 kHz
DC REF 650K
MESR 450 kHz
J14-B1
J14-A1
PROBE
REF
J2-A2
FC OUT
A IN 450 kHz
D OUT 650 kHz
MESR 650 kHz
J2-B2
A IN 650 kHz
MESP 450 kHz
J2-C3
MESP 650 kHz
J2-C4
Photodetector1.2 V/u W
InGaAs
LIMITER
PROBE
DC PROBE 450K
DC PROBE 650KJ14-C2
J14-C1
D OUT 200 kHz
D IN 450 kHz
D IN 650 kHz
PhotodetectorINOPT1
INEL1
DET1 OUT
OUT 450 kHz
1.2 V/u W
InGaAs
INOPT2
INEL2
DET2 OUT
OUT 650 kHzPhotodetector1.2 V/u W
InGaAs
D OUT 450 kHz
FC OUT
A IN 450 kHz
D OUT 650 kHzA IN 650 kHz
D OUT 200 kHz
D IN 450 kHz
D IN 650 kHz
MIXER
REF REF REF
PROBE
PROBE
D IN 200 kHz
FC IN
TRIG
RESET
D IN 200 kHz
FC IN
DIGITAL PM
PREAMPFILTER
J29 J6
J35 J7
J30J15 J32
J33
J53
J31 J16
J20 J21 J6 J10
J15
J12 J13 J5
J9 J18 J19
J34 J8
J38 J9
J36J17 J37
J40
J54
J39 J18
J41 J10
J47 J11
J42J19 J44
J45
J55
J43 J20
J46 J12
J50 J13
J48J21 J49
J52
J56
J51 J22
J22 J23 J7 J11
J16 J17 J8 J12
J14
J18 J19 J9 J13
J15 J17 J7
J10 J22 J23
J14 J16 J6
J20 J21 J8
J66
J60
J61
J64
J65
J62
J63
GND
GND
GND
GND
OverLoadProtection
OverLoadProtection
OverLoadProtection
OverLoadProtection
Institute of Microtechnology, Neuchâtel OS, 8.5.2003
H
Annex H
Datasheet of the Photodetector
InGaAs photodetector. Frequency and noise spectra.
-40
-30
-20
-10
0
10
20
Am
plitu
de [d
B]
101
102
103
104
105
106
107
108
Frequency [Hz]
-300
-200
-100
0
100
200
Phase [deg]
-140
-120
-100
-80
-60
Am
plitu
de [d
Bm
/Hz]
102
103
104
105
106
107
Frequency [Hz]
-140
-120
-100
-80
Am
plitu
de [d
Bm
/Hz]
2.0x106
1.51.00.50.0Frequency [Hz]
7.5MHz @-3dB
-128dBm/Hz
Fig. 2: 100Hz to20MHz
Fig. 3: 10Hz to2MHz
Fig. 1
-115dBm/Hz
InGaAs photodetector.Specifications: Photodiode 100um InGaAs pigtailedResponse 800 to 1800nm (Fig.4)Transimpedance gain 1.4 x 10 exp 6 V/ABandwith DC to 7.5MHzOut Voltage in Volt/uW, @1300 nm 1.2 V/uWOutput impedance 50 OhmsOutput voltage (50 Ohms ) 0 to 1.7 VOutput voltage (HI-Z ) 0 to 3.4 VOffset AjustableNoise (typical) from 10 Hz to 800KHz -128 dBm/HzNoise max @ 6MHz -115 dBm/HzNEP @1300nm 0.14 pW/rootHz
Power requirements +5V / 60mA Max +6V !0V common-5V / 60mA Max -6V !
Responsivity of the photodiode. Fig.4
Institute of Microtechnology, Neuchâtel OS, 23.5.2003
I
Annex I
PLD Design of the Phasemeter
MAX+plus II 9.6 File: PHASESHIFTER200-REF2QD-03-05-07.GDF Date: 05/08/2003 15:37:23 Page: 1
w2s
ReferenceINPUT
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
Clear INPUTC
Clock INPUTC
LPM_AVALUE=
LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=
LPM_WIDTH=10
updown
cnt_en
clk_en
q[]
LPM_COUNTER
LPM_AVALUE=
LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=
LPM_WIDTH= 9
cnt_en
clk_en
aclr
q[]
LPM_COUNTER
NOT
NOT
Clock2OUTPUT
PLLOUTPUT
Ref2OUTPUT
Clock1OUTPUT
RefQOUTPUT
VCC
VCC
VCC
VCC
TRI
RefQ
Reference
PS[8..0]
PLL,P[8..2],Clock2,P0
PS8 RefQ
MAX+plus II 9.6 File: PHASEMETER200_CLKEN-03-05-07.GDF Date: 05/08/2003 15:36:49 Page: 1
LPM_AVALUE=
LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=
LPM_WIDTH=10
sload
updown
cnt_en
data[]
clk_en
aclr
q[]
LPM_COUNTER
LPM_AVALUE=
LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=
LPM_WIDTH=19
updown1
cnt_en
clk_en
aclr
q[]
LPM_COUNTER
LPM_AVALUE=LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=
LPM_WIDTH=10
sload
updown
cnt_en
data[]
clk_en
aclr
q[]
LPM_COUNTER
RefQ INPUT
ReferenceINPUT
NoError INPUT
Clock INPUTC
Signal INPUTC
Clear INPUTC
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
VCC
VCC
VCC
AND2
AND2
AND2
NOT
NOT
NOTNOT
NOT
NOT
F[9..0]OUTPUT
I[18..0]OUTPUT
ReadyOUTPUTC
LPM_AVALUE=
LPM_WIDTH=10
aclr
data[]
gate
q[]
LPM_LATCH
LPM_AVALUE=
LPM_WIDTH=2
aclr
data[]
gate
q[]
LPM_LATCH
LPM_AVALUE=
LPM_WIDTH=10
aclr
data[]
gate
q[]
LPM_LATCH
NOR2
XNOR
XNOR
XOR
WIDTH=10
result[]
datab[]
sel
dataa[]0
1
BUSMUX
LATCH
QENA
D
AND3
NOR3
OR2
Signal
A[9..0]
K1
Clock
CntB8
B9
Clear
A9
K[1..0]Cnt,UD
UDA8
Start2
K0
A7B[9..0]
SELECT
X1,X0,B[7..0]
X1
FR[9..0]FR[9..0]
A[9..0]X0
Clear
MAX+plus II 9.6 File: PHASEADDER200-03-05-07.GDF Date: 05/08/2003 15:35:53 Page: 1
PK[3..0] INPUT
Clock INPUT
Trigger INPUT
Ready INPUT
F[9..0] INPUT
I[18..0] INPUT
OE INPUTLPM_DIRECTION=
LPM_PIPELINE=
LPM_REPRESENTATION="SIGNED"
LPM_WIDTH=49
MAXIMIZE_SPEED=
ONE_INPUT_IS_CONSTANT=
datab[]
cout
result[]
dataa[]
cin
LPM_ADD_SUB
A[1..0] INPUTC
Clear INPUTC
GND
GND
D
DFFE
ENACLRN
QPRN
D
DFFE
ENACLRN
QPRN
D
DFFE
ENACLRN
QPRN
D
DFFE
ENACLRN
QPRN
O[31..0]OUTPUT
LPM_AVALUE=1
LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=
LPM_WIDTH=20
sload
updown
cnt_en
data[]
clk_en
aclr
1
q[]
LPM_COUNTER
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
VCC
VCC
VCC
VCC
NOT
NOT
NOTNOT
AND2
LPM_AVALUE=
LPM_WIDTH=20
aclr
data[]
gate
q[]
LPM_LATCH
LPM_AVALUE=
LPM_WIDTH=49
aclr
data[]
gate
q[]
LPM_LATCH
LPM_PIPELINE=
LPM_SIZE= 3
LPM_WIDTH=32
LPM_WIDTHS=CEIL(LOG2(LPM_SIZE))
data[][]
sel[]
result[]
LPM_MUX
TRI
S
R
SRFF
Q
CLRN
PRN
U[19..0]
MUX[31..0]PK[3..0],SOT[3..0],L[6..0],AP[48..0],L[11..0],N[19..0]
AP[48..0]
U[19..0],T[28..0]T28
T[28..0]I[18..0],F[9..0]
A[1..0]
LOADR[48..0]S[48..0]
Clear
C[19..0]
N[19..0]C[19..0]
EN_CNT_REG
L[6..0]
PK[3..0]
STOP
SOT3,SOT2,SOT0
SOT1
MAX+plus II 9.6 File: FRINECOUNTER-03-05-07.GDF Date: 05/08/2003 15:34:31 Page: 1
Clock INPUTC
Clear INPUTC
Signal INPUTC
Reference INPUTC
LPM_AVALUE=
LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=
LPM_WIDTH=24
cnt_ena
clr
q[]
cout
LPM_COUNTER
LPM_AVALUE=
LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=
LPM_WIDTH=24
sload
updown
cnt_en
data[]
clk_en
aclr
q[]
cout
LPM_COUNTER
LPM_DIRECTION="SUB"
LPM_PIPELINE=1
LPM_REPRESENTATION="SIGNED"
LPM_WIDTH=25
MAXIMIZE_SPEED=10
ONE_INPUT_IS_CONSTANT=
datab[]
cout
result[]
dataa[]
cin
aclr
clock
LPM_ADD_SUB
Q[24..0]OUTPUTC
GND
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
VCC
VCC
VCC
NOT
NOT
TRI
OE INPUT
P[24..0]
MAX+plus II 9.6 File: ADDRESSER-03-05-07.GDF Date: 05/08/2003 15:32:51 Page: 1
PK[3..0]
Clock INPUT
Clear INPUT
Trig INPUT
LPM_AVALUE=
LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=
LPM_WIDTH=4
aclr
q[]
LPM_COUNTER
LPM_AVALUE=
LPM_DIRECTION=
LPM_MODULUS=
LPM_SVALUE=LPM_WIDTH= 9
cnt_en
clk_en
aclr
q[]
LPM_COUNTER
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRND
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
D
DFF
CLRN
QPRN
VCC
VCC
VCC
VCC
VCC
ADRDOUTPUT
ADWROUTPUT
OE4OUTPUT
LoadOUTPUT
ADCSOUTPUT OE3OUTPUT
ClearDetOUTPUT
OE2OUTPUT
TrigDetOUTPUT
A1OUTPUT
PKCNT[3..0]OUTPUT
A0OUTPUT
OE1OUTPUT
STROBEOUTPUT
NOT NOT
NO
T
NOT
NOT
NOT
NOT
NOT
NOT
NOT
NOT
AND2
AND2
AND2
AND2
AND2
AND2
AND2
AND2
S[8..0]
B6B5B4B3B2B1B0
S5
PKCNT[3..0]
B4
B5
Load
ADCSADRD
B6
ADWR
ADWRLoadADCSADRD
S2
Institute of Microtechnology, Neuchâtel OS, 8.5.2003
J
Annex J
Pinout of the Instantaneous
Phase Connector
+5 V
REQ1
ACK1
STOPTRIG1
PCLK1
PCLK2
STOPTRIG2
ACK2
REQ2
DIOA0
GND
DIOA3
DIOA4
GND
DIOA7
DIOB0
DIOB1
GND
RGND
GND
DIOB6
DIOB7
DIOC0
GND
DIOC3
DIOC4
GND
DIOC7
DIOD0
GND
DIOD3
DIOD4
GND
DIOD7
RGND
GND
DPULL
CPULL
GND
GND
RGND
GND
GND
DIOA1
DIOA2
GND
DIOA5
DIOA6
GNDGND
DIOB2
DIOB3
DIOB4
DIOB5
GND
RGND
DIOC1
DIOC2
GND
DIOC5
DIOC6
GND
DIOD1
DIOD2
GND
DIOD5
DIOD6
GND
1 35
2 36
3 37
4 38
5 39
6 40
7 41
8 42
9 43
10 44
11 45
12 46
13 47
14 48
15 49
16 50
17 51
18 52
19 53
20 54
21 55
22 56
23 57
24 58
25 59
26 60
27 61
28 62
29 63
30 64
31 65
32 66
33 67
34 68
AMP 2-174225-5 68-Pos Right AnglePWB-Mount Connector (Male)
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