3.1

Laser signal strength variation and zero-crossing level.

Fig. 6 shows the conversion from sinusoid to square wave. At JPL, the device that performs this function is called a “Post-Amp” and we will use this term. (Postamps also perform signal amplification and conditioning, so the name is reasonable.)

Fig. 6.

Conversion of sinusoid to square wave. Dashed connections indicate optional hysteresis circuits.

The amplitude of the sine wave input is proportional to the laser power and to the interferometric fringe contrast which, in real-world systems, can be expected to vary a few percent. (This is particularly true for fiber-optic coupled interferometers, where temperature changes affect polarization, affecting the fringe contrast.)

Since typical JPL testbeds have heterodyne signal amplitude drift R_A=5%, if we want ε(ϕ)≈10^-5 cycle stability, the amplitude-to-phase coupling dϕ/dR_A must be less than 2x10^-4.

The phase of the output square wave will not be affected by the input amplitude drift if

Requirements 1 and 2 will be approximately satisfied if low-distortion op-amps [9] are used upstream and are operated at low enough gain and amplitude to be far from their slew-rate and gain-bandwidth limitations. Example: if the op-amp GBWP=10 MHz and F_HET=100 kHz, then the G must be < 100, preferably less. Similarly, if the slew-rate R=10V/μs, the gain must be < R/(2πF_HET)=16. Evidently, the slew rate limitation is the more constraining.

Requirement 3 is problematic since all electronics experience some DC drift with temperature changes. Op-amp output drift can be eliminated by AC coupling, but comparator input offset, which is usually zeroed using an external potentiometer, cannot be eliminated. Quantitatively, a comparator offset voltage will cause a phase sensitivity

in units of cycles, and where V_pp is the comparator input amplitude. Example: if V_pp=2 Volts, and we require dϕ/dR_A<2x10^-5, then V_offset must stay within +/- 0.13 mV. A typical comparator offset temperature coefficient is 0.01 mV/C, so for this example a 13 C range would be acceptable, ignoring all other effects.

The reader might suggest that using an automatic gain control (AGC) circuit would eliminate the amplitude variation problems just discussed, however it has proven difficult to construct an AGC circuit that doesn’t introduce its own phase changes.

A practical obstacle in evaluating dϕ/dR_A is that amplitude modulated sine wave sources that are free of phase modulation at the 10^-6 level are not readily available. An approach we have found we can trust is shown in Fig. 7. Its advantage is that by using the same photodiode and electronics as in the final application, parasitic phase shifts are automatically taken into account.

Fig. 7.

Set up for testing amplitude-to-phase coupling. Signal generator set to F_HET drives LED and reference channel post-amp. Neutral density filter moved in/out of gap between LED and p.d., causes a varying amplitude but constant phase signal. The phase meter detects any spurious phase shift by comparing the two post-amp outputs.

3.2

Thermal stability of zero-crossing detector

Comparator offset drift ε(V_offset) will, by itself introduce a phase drift

in cycles. Example: V_pp=2 Volts, then for ε(ϕ)≈10^-5 cycles, ε(V_offset) must be less than .063 mV. If the comparator offset temperature coefficient is 0.01 mV/C, then a 6.3 C range would be acceptable, ignoring all other effects.

The offset drift problem will be worsened by the addition of a hysteresis feedback resistor (Fig. 6, needed for a glitch-free square-wave output) which will couple comparator output drift (or power supply drift) to the input. This can be solved by using a capacitor instead of a resistor. The capacitor value must be carefully chosen to provide enough feedback to debounce the output, but not so much as to noticeably retard the output phase.

In practice, the current solution to the comparator drift problem is to stabilize the temperature, placing the electronics in a constant-temperature oven.

3.3

Thermal stability of bandpass filters

Another source of phase drift is the bandpass filters that are generally needed to remove RF pickup and noise from the photodiode signals. The circuit in Fig. 8 attenuates all frequencies outside of the band ω_hp<ω_HET<ω_lp, where we are working in radians/s, ω≡2πF. There is a phase shift associated with the high-pass and low-pass filters which change the phase by tan^-1(ω_hp/ω_HET) and tan^-1(ω_HET/ω_lp) respectively. ω_hp and ω_lp are determined by resistance and capacitance values which will drift with temperature. Low drift thin-film resistors are readily available, but even good quality capacitors [10] will drift ~0.01% per degree C.

Fig. 8.

Bandpass filter that allows through frequencies between ω_lp=(R_lpC_lp)^-1 > ω > ω_hp=(R_hpC_hp,)^-1 radians/s. In practice, the buffer separating the low-pass and high-pass sections can be eliminated if R_lp ≪ R_hp, (making it easy to modularise the bandpass filters).

The change in phase per change in capacitance can be predicted: Let u=ω_hp/ω_HET. A fractional increase in capacitance will cause an equal fraction decrease Δu/u, which will in turn cause a phase shift

Example: if F_HET=100 kHz, and the high-pass and low-pass frequencies are 50 kHz and 200 kHz respectively, so that for high-pass u=1/2 and for low-pass u=2. A 0.01% change in capacitor values (as expected for a 1 degree C change) will cause a phase shift Δϕ=(0.5)/(1+(0.5)²)(0.0001)=4x10^-5 radians =6.4x10^-6 cycles.

It should be remembered that an equal contribution also comes from the low-pass filter. Indeed, if there are N bandpass filters, the drift will be multiplied by 2N. So for 4 bandpass filters, a 1 degree C change causes Δϕ=5.1x10^-5 cycles. Doubling the frequency range to 25 to 400 kHz would reduce Δϕ to 3x10^-5 cycles.

4.1

Glitch removal with phase-locked-loops

The addition of a phase-locked loop (PLL) [11] is a potent cure for glitches. Conceptually, the PLL is variable, voltage controlled frequency oscillator (VCO) with a mechanism that makes it closely follow the frequency and phase of the square wave from the zero crossing detector. In principle, the phase of the PLL output oscillator is equal to the zero-crossing phase plus a constant offset, usually 90 degrees. Input glitches are ignored by the PLL oscillator, which supplies a clean square wave to the phasemeter.

In practice, the phase relationship between the PLL input and output drifts with temperature. For the 74HC4046 we see roughly 2.5x10^-4 cycles/C sensitivity. Further work should greatly improve this aspect of the circuit.

An additional benefit of the PLL technique is that it allows glitch-free measurement of low S/N signals, allowing much lower laser power. We are taking advantage of this in the JWST dilatometer where low sample heating, low incident power, are required.