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Timing Jitter

Definition: fluctuations of the temporal positions of pulses

Alternative term: timing noise

More specific terms: Gordon–Haus jitter, pulse-to-pulse jitter

German: zeitliche Fluktuationen

Categories: fluctuations and noise, optical metrology

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Cite the article using its DOI: https://doi.org/10.61835/p6i

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Pulse trains, generated e.g. in mode-locked lasers, exhibit some deviations of the temporal pulse positions from those in a perfectly periodic pulse train. This pheno­menon is called timing jitter and is important for many applications, e.g. for long-range optical fiber communications or for optical sampling measurements.

Similarly, light pulses from Q-switched lasers exhibit timing jitter, although the involved physical mechanisms are very different.

Another type of timing jitter occurs in photodetectors, as also discussed below.

Types and Quantification of Timing Jitter

The timing deviations considered can be of different kinds:

  • the deviations between the temporal pulse positions and those of perfectly regular clock ticks
  • the deviations between the temporal pulse positions and those of the ticks of a real (noisy) oscillator (e.g. the electronic oscillator which drives the modulator of an actively mode-locked laser)
  • the deviations of the pulse-to-pulse spacing from the average pulse period (pulse-to-pulse jitter or cycle jitter)

In telecom systems, the relevant jitter can be that between data-carrying pulses and a clock signal. The latter may have been extracted from the data stream itself, or transmitted separately. In the former case, the low-frequency jitter is transferred to the extracted clock signal, and often is not relevant for detection.

Timing errors may be quantified (→ noise specifications) in different ways:

Timing Jitter of Mode-locked Lasers

For optical pulses, timing jitter is related to phase noise in the optical frequency components of the pulse train (see below). In the absence of technical noise, the jitter of a mode-locked laser is limited by quantum noise, but in most cases it is dominated by vibrations and drifts of the laser resonator. Important theoretical results, based on analytical and numerical modeling, are discussed in Refs. [5, 12, 13, 15].

timing jitter spectrum of a passively mode-locked laser
Figure 1: Theoretically calculated quantum-limited timing jitter spectrum of a 10-GHz Er:Yb:glass miniature laser (with single-sideband noise in dBc/Hz, obtained as <$10 \: \lg S_{\varphi}(f)$>). In reality, the low-frequency noise (e.g. below 10 kHz) is higher due to technical noise. To some extent, relaxation oscillations (at ≈ 230 kHz) are converted into timing jitter. With a feedback system, the long-term timing drift can be suppressed, so that the low-frequency jitter is strongly reduced.

The timing jitter of various kinds of mode-locked lasers (e.g. miniature bulk lasers, fiber lasers, or external-cavity diode lasers) can be very small – often significantly smaller than that of high-quality electronic oscillators. This applies particularly to short time scales, where a laser can be used as a very precise timing reference (as a kind of flywheel). The long-term timing drifts can also be suppressed to extremely small levels using self-referenced frequency combs.

Timing Jitter and Phase Noise

In order to avoid confusion, one should be aware that there are two fundamentally different kinds of phase noise in the context of ultrashort pulse lasers:

  • One can convert the timing jitter into a timing phase noise, where the PSD carries units of fs2/Hz, for example. This is just another way of specifying the magnitude of timing jitter. For a given pulse repetition rate <$f_\textrm{rep}$>, the PSD of the timing phase noise can be calculated from that of the original timing noise with the following equation:
$${S_\varphi }(f) = {\left( {2\pi {f_0}} \right)^2} \: S_t(f)$$
  • There is noise of the optical phase (optical phase noise), which is a fundamentally different phenomenon, although there are certain relations between both types of phase noise [15].

Measurement of Timing Jitter

There are a variety of different methods for measuring the timing jitter of mode-locked lasers:

  • The popular von der Linde method [2] is based on the evaluation of RF spectra of photodiode signals. It is fairly simple, but rests on assumptions (small fluctuation amplitudes, no correlations between intensity and phase fluctuations, etc.) which are not always well satisfied, and is subjected to various technical limitations. In particular, phase noise of the local oscillator of the electronic spectrum analyzer can affect the results [14].
  • The phase detector method (see e.g. [3]) is often applied to actively mode-locked lasers, where the laser timing is compared with that of the electronic driver signal (residual jitter). It is not easy to achieve good suppression of the influence of intensity noise, particularly due to the phenomenon of drifting mixer offsets.
  • The relative timing jitter of free-running passively mode-locked lasers (but also of synchronized lasers) can be measured with a versatile method based on a beat note of photodiode signals, generated with appropriate RF techniques and numerical processing [14]. This method is very versatile, extremely sensitive, and relatively immune to a range of problems as frequently encountered with other methods. It is not affected by electronic oscillator noise and mixer offsets, and only very weakly by intensity noise. By comparison of different lasers, the absolute timing jitter can be obtained. For example, if one laser is known to have a lower jitter, the measured relative jitter is close to the absolute jitter of the other laser. If both lasers are very similar but uncorrelated, the recorded power spectral density at each noise frequency is twice that of a single laser.
  • Very precise measurements are possible with a balanced optical cross-correlator based on a χ(2) nonlinear crystal [18, 32]. One may, e.g., compare the timing of two mode-locked lasers. The r.m.s. noise floor in a 10-MHz bandwidth, for example, can be well below 1 fs. Note that this method allows one to measure timing deviations only if the pulses have a quite low distance, e.g. up to 100 fs. Therefore, it is usually applied only to timing-stabilized lasers, exhibiting bounded timing fluctuations.

Timing Jitter of Q-switched and Gain-switched Lasers

In an actively Q-switched laser, there is some time delay between the opening of the Q switch and the generated pulse. The magnitude of that time delay is subject to fluctuations, so that a timing jitter results even if the modulator signal is very regular. The origin of that jitter may be fluctuations of the pump power, but thermal effects, vibrations and other disturbances can also contribute. A variation of the pulse timing by more than the pulse duration (Figure 2) is not unusual in such lasers, and is a problem particularly in cases where pulses from different lasers must be synchronized (e.g. for sum and difference frequency generation). The jitter can be reduced e.g. with injection seeding.

timing jitter of an actively Q-switched laser
Figure 2: Simulated timing jitter of an actively Q-switched laser, caused by fluctuations of the pump power. The timing fluctuations are strongly correlated with those of peak power and pulse duration.

In passively Q-switched lasers, fluctuations of pump power may lead to a larger timing jitter, as a pulse is emitted as soon as the laser gain becomes high enough to overcome the losses; that time is affected by pump power fluctuations, for example. On the other hand, noise of the pulse energy is reduced with that technique.

If pulses from an actively Q-switched laser are used in a timing-critical setup, it can be a good approach to trigger that setup with a photodiode signal indicating the pulse arrival times, rather than with the modulator signal.

Gain-switched lasers (e.g. some picosecond diode lasers) also exhibit relatively large timing jitter, compared with mode-locked lasers.

Timing Jitter of Photodetectors

When a photodetector such as a photodiode is used for measuring pulse arrival times, the photocurrent also exhibits some timing jitter, and the timing error in the measured result may be further increased by noise in the detector electronics.

Details such as r.m.s. jitter and the shape of the probability distribution depend very much on the type of detector. For example, avalanche photodiodes in Geiger mode, used as SPADs (single-photon avalanche detectors), have other noise characteristics than ordinary photodiodes used at higher optical signal levels. The r.m.s. jitter of a fast SPAD can be below 100 ps for single-photon detection. Averaging over multiple pulses can be used to further reduce the effective jitter.

In the detection of pulse trains for mode-locked lasers, saturation effects are often a limiting factor: the peak power must be limited in order to avoid saturation, and this results in a low average power and thus a poor signal-to-noise ratio. A possible solution is to use a source with a high pulse repetition rate, or to increase the repetition rate of an existing source by repetition rate multiplication using interferometers [24].

Shot noise is a limiting factor for the precision with which the pulse position (defined as a “center of gravity”) can be determined. For a given pulse energy, the shot noise impact is higher for longer pulses [13]. Curiously, however, the shot noise limit for photo-detected pulses in a coherent pulse train is not determined by the photodetector's temporal resolution: due to correlations in the photocurrent spectrum, the noise limit can be lower for shorter optical pulses, even if this does not result in shorter detected pulses [30].

Suppliers

The RP Photonics Buyer's Guide contains two suppliers for timing jitter measurement devices. Among them:

Bibliography

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(Suggest additional literature!)

See also: noise specifications, timing phase, laser noise, phase noise, mode-locked lasers, frequency combs, Gordon–Haus jitter, synchronization of lasers

Questions and Comments from Users

2020-05-25

What is considered to be a low value of timing jitter? Any value lower than the pulse-to-pulse separation? Or any value lower than the temporal pulse width?

In an optical sampling experiment, what would be considered a small enough value of jitter so that the effect is negligible?

The author's answer:

It depends very much on the application what value of timing jitter is considered as low. In your example of optical sampling, one would usually require that the r.m.s. timing deviation is well below the pulse duration.

Note that timing jitter cannot always be specified in units of seconds – in particular, if there are unbounded timing drifts.

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