Flicker is a directly visible change in brightness of a light source which can be due to fluctuations of the light source itself, or due to external causes such as due to rapid fluctuations in the voltage of the power supply or incompatibility with an external dimmer.
Effects
Various scientific committees have assessed the potential health, performance and safety-related aspects resulting from temporal light modulations including light flicker. Adverse effects of flicker of include annoyance, reduced task performance, visual fatigue, headache and epileptic attack by photosensitive persons. The visibility aspects of flicker are given in a technical note of CIE; see CIE TN 006:2016. In general, undesired effects in the visual perception of a human observer induced by light intensity fluctuations are called Temporal Light Artefacts].
Root causes
Light emitted from lighting equipment such as luminaires and lamps may vary in strength as function of time, either intentionally or unintentionally. Intentional light variations are applied for warning, signalling, entertainment with the purpose that flicker is perceived by people. Generally, the light output of lighting equipment may also have unintentional light level modulations due to the lighting equipment itself. The magnitude, shape, periodicity and frequency of the TLMs will depend on many factors such as the type of light source, the electrical mains-supply frequency, the driver or ballast technology and type of light regulation technology applied. If the modulation frequency is below the flicker fusion threshold and if the magnitude of the TLM exceeds a certain level, then such TLMs are perceived as flicker. These TLM-properties may vary over time due to aging effects. Component failure within lighting equipment or end-of-life behavior of lighting equipment can also give rise to flicker. Furthermore, external factors such as incompatibility with dimmers or presence of mains-supply voltage fluctuations are root causes of flicker. Flicker can also be perceived from naturally modulated light sources like candle light or a sunlit water surface or it may be experienced while driving along a row of trees lit by the sun. TLMs and resulting flicker can be seen also while driving with a certain speed along a street or through a tunnel lit by lighting equipment positioned with a regular spacing.
Visibility
Temporal light modulations become visible if the modulation frequency is below the flicker fusion threshold and if the magnitude of the TLM exceeds a certain levels. There are much more factors that determine the visibility of TLMs as flicker:
The shape properties of the light waveform ; see Figure 1;
The average light level of the light source and its contrast with the background light level within the environment;
The viewing angle and changes in direction of view by the observer;
Physiological factors such as age and fatigue.
All observer-related influence quantities are stochastic parameters, because not all humans perceive the same light ripple in the same way. That is why perception of flicker is always expressed with a certain probability. Detailed explanations on the visibility of flicker and other temporal light artefacts are given in CIE TN 006:2016 and in a recorded webinar “Is it all just flicker?”.
Objective assessment of flicker
Light flickermeter
For objective assessment of flicker, a widely applied and IEC-standardized metric, the short-term flicker indicator is used. This metric is derived from the short term flicker severity metric PstV that is applied in the power quality domain for testing electrical apparatus for their potential to cause flicker via voltage fluctuations on the electrical mains network. The short-term flicker indicator PstLM is implemented in a light flickermeter which processes the light measured by means of a light sensor. The light flickermeter consists of four processing blocks which include weighting filters to account for frequency dependency of the visibility of TLMs as well as statistical processing to enable assessing a-periodic TLMs. The specification of the light flickermeter and the test method for objective flicker assessment of lighting equipment is published in IEC technical report IEC TR 61547-1. It is recommended to calculate the value of PstLM using a light waveform recorded for at least three minutes. This enables proper assessment of flicker occurring at low repetition frequencies. NOTE - Several alternative metrics such as Modulation Depth, Flicker Percentage or Flicker Index are being applied. None of these metrics are suitable to predict actual human perception because human perception is impacted by modulation depth, modulation frequency, wave shape and if applicable the duty cycle of the TLM.
A Matlab light flicker assessment toolbox including a function for calculating PstLM and some application examples are available on the Matlab Central via the Mathworks Community.
Acceptance criterion
The perceptibility scale of PstLM is chosen such that a value of 1.0 corresponds to a level at which 50% of human test subjects judge the flicker to be both noticeable and irritating.
Test and measurement applications
The objective light flickermeter can be applied for different purposes :
Measurement the intrinsic flicker performance of lighting equipment when supplied with a stable mains voltage;
Testing the immunity of lighting equipment against voltage fluctuation disturbances on the AC mains;
Testing the effect of light regulation of lighting equipment or the effect of an external dimmer.
Publications of standards development organisations
IEC TR 61457-1:2017: light flickermeter specification and verification method, and test procedure for voltage fluctuation immunity and dimmer compatibility.
NEMA 77-2017: among others, flicker test Methods and guidance for acceptance criteria.