The base of laser beam diagnostic is to know how much average power you got. Available off the shelves form different manufacturers are three main type of devices, based either on a photodiode, a thermopile or a pyroelectric detector.

Of course, many factors will influence the quality of a power meter, the most important being its calibration. One should go for power meters which calibration is traceable to a recognised standard (such as NIST).

Photodiodes: precision for low power lasers.

When a photon source, such as a laser, is directed at a photodiode detector, a current proportional to the light intensity and dependent on the wavelength is created. A photodiode sensor has a high degree of linearity over a large range of light power levels - from fractions of a nanowatt to about 2 mW (this higher limit depends a bit on the photodiode). Above that light level, corresponding to a current of about 1mA, the electron density in the photodiode becomes too great and its efficiency is reduced causing saturation and a lower reading. Most manufacturers offer a removable ND filter to allow extending somewhat the dynamic range of the power meter, generally up to about a watt maximum.

Photodiodes are generally made of silicon, thus their response is typically 350-1100 nm, and can be extended to 200-1100 nm. Occasionally one can find an off the shelf calibrated germanium or InGaAs photodiode which will allow precise measurement on the 800-1600 nm range. As you can see on the picture below, the typical response curve of a silicon photodiode is highly wavelength-dependent.

Silicon reponse curve

This importance of the wavelength dependence leads to two main drawbacks: you need to have a clear idea of the wavelength of your laser, since the power meter will ask you for it and the result will depend on the answer. Plus photodiode power meters are inappropriate for broadband light sources power measurements (for instance it is not the way forward when using femtosecond lasers).

On the positive side, photodiodes are relatively insensitive to temperature fluctuations, have a very small form factor, are fast (from a fraction of a second to some tens of microsecond response time, limited by the electronic) and are insensitive to vibrations. But their main and unique advantage lies in their ability to measure very small optical power.

Some manufacturers even offer a background light cancellation feature, which uses a second photodiode placed outside of the laser beam path but close enough to the measuring photodiode. The light measured by this second photodiode is considered as the background noise and subtracted to the reading of the first one.

Thermopiles: stability for medium and high powers

Using a thermopile sensor is a very robust and well established way to measure laser energy. The underlying principle is quite simple: it uses some thermocouples to measure the temperature gradient between the point where the laser beam hit the thermopile and the periphery where the heat is dissipated using a heatsink. It is then easy to calculate the incident laser power.

Thermopiles tend to be more accurate than photodiodes, but their sensitivity is lower. This means the error is lower in percentage, but they are unable to measure low power lasers. Typically their power range can go as low as a few hundreds of microwatt while some high power thermopile sensors can measure up to nearly 10 kW. Usable wavelength range commonly span 200-20,000 nm for a single broadband sensor.

On the down side, they are slow, at generally a couple of second response time despite software acceleration. Plus, since the measurement is based on heat exchange, a quick fluctuation of housing temperature will decrease the accuracy of the result. This is an issue for instance if the beam hits the housing or if you hold a low power thermopile by hand. Keep in mind that part of the beam energy is distributed outside the defined beam diameter, and this energy can hit the housing if your beam is too large.

Due to their slow response time, they are only really capable of measuring average power. They generally have an energy mode which allow them to measure the energy of a single pulse. Interestingly, the pulse width does not really matter: however short, the energy of the pulse will produce a heat increase and thus the meter will deliver a reading. However some thermopiles are better equipped to measure short pulses with high energy: in this situation the energy needs to be absorbed in the volume of the absorber and not only on its surface, otherwise there is a possibility to damage the sensor.

Because the measurement relies on thermal exchanges, thermopile technology is quite diverse. One can find sensor specialised on short pulses, some on long pulses, some give better results at specific wavelength, some have a spectrally flat response over hundreds of nanometer allowing broadband light measurement, and some have a slightly different technology, based on a Peltier device, which allows sub-second response time.

Pyroelectric: energy and power

Some applications absolutely need a pulse-to-pulse measurement of the energy. In those situation where an average reading of the power is not enough, a pyroelectric energy meter is the way forward.

Pyroelectricity is the ability of certain materials (generally a polar crystal or a ferroelectric) to generate an electrical potential when they are heated or cooled. When a pulse of light hits the detector, it heats it up and create that electric potential. The electrical voltage read by the measuring instrument is then proportional to the energy. Average power can be calculated by the electronic.

Pyroelectric energy meters are very fast (up to tens of kHz) and very broadband (typically 200-20,000 nm). These energy detectors will also make accurate measurements in spite of changing temperature in the environment or heating of the detector.

Unfortunately they are less durable and less accurate than thermopiles or photodiodes. They are also sensitive to vibrations and can’t measure continuous light (CW lasers) nor long pulses (it typically has to be less than 10 ms, but this varies a lot from detector to detector). It also has a maximum repetition rate. Therefore they should only be used when the measure of each pulse energy is necessary.

The level of laser exposure which is considered as the limit between safe and potentially harmful is called Maximum Permissible Exposure (or MPE). Maximum Permissible Exposures are set by the International Commission on Non-Ionizing Radiation Protection (ICNIRP) and are also adopted by standardisation committees.

As Maximum Permissible Exposure evaluation and the determination of hazard areas (NHZ: Nominal Hazard Zone) are quite involved, a laser safety classification scheme has been designed by international standardisation committees to help users to decide if their laser is a potential hazard. Below is a summary of the different laser classes with their description.

Class 1

• Meaning: safe
• Type of laser: very low power lasers or enclosed lasers.
• Maximum Permissible Exposure: is never exceeded, even for very long exposure (hours), or with the use of optical instruments.
• Nominal Hazard Zone: none.
• Typical Accessible Emission Limit*: 40 µW for blue.

Class 1M

• Meaning: safe for the naked eye only, but potentially hazardous when optical instruments** are used.
• Type of laser: medium power lasers either collimated with a large beam or highly divergent.
• Maximum Permissible Exposure: can be exceeded when using optical instruments**.
• Nominal Hazard Zone: none for the naked eye.
• Typical Accessible Emission Limit*: a laser can be classified as Class 1M if the total output power is below class 3B (0.5 W for continuous in the visible) but the power that can pass through the pupil of the eye is within Class 1.

Class 2

• Meaning: safe for unintended exposure, (less than 0.25 s) but hazardous when looking at for more than 0.25 s.
• Type of laser: visible (400–700 nm) low power lasers.
• Maximum Permissible Exposure: are not exceeded provided the viewings are accidental only. MPE calculation assumes the blink reflex will stop the light after 0.25 s
• Nominal Hazard Zone: none for accidental exposure.
• Typical Accessible Emission Limit*: 1 mW for continuous lasers.

Class 2M

• Meaning: safe for the naked eye when the exposure is unintended, (less than 0.25 s) but hazardous when looking at for more than 0.25 s or when optical instruments** are used.
• Type of laser: visible (400–700 nm) medium power lasers either collimated with a large beam or highly divergent.
• Maximum Permissible Exposure: are not exceeded provided the viewings are accidental only and only with naked eyes. MPE calculation assumes the blink reflex will stop the light after 0.25 s. Using optical instruments** might bring the exposure above the MPE as well.
• Nominal Hazard Zone: none for accidental exposure to the naked eye.
• Typical Accessible Emission Limit*: a laser can be classified as Class 2M if the total output power is below class 3B (0.5 W for continuous in the visible) but the power that can pass through the pupil of the eye is within Class 2.

Class 3R

• Meaning: unsafe, except when handled carefully by experienced users. Accidental short exposure is considered as a small hazard.
• Type of laser: low power lasers.
• Maximum Permissible Exposure: can be exceeded up to 5 times.
• Nominal Hazard Zone: hazard area for the eye, none for the skin.
• Typical Accessible Emission Limit*: typically 5 mW in the visible.

Class 3B

• Meaning: unsafe without exception, Personal Protective Equipment (laser safety goggle) must be worn within the nominal hazard zone. Focused lasers of this class are a potential fire hazard.
• Type of laser: medium power lasers.
• Maximum Permissible Exposure: is exceeded more than 5 times. Skin MPE is not generally exceeded, except at focus.
• Nominal Hazard Zone: hazard area for the eye, none for the skin.
• Typical Accessible Emission Limit*: 500 mW.

Class 4

• Meaning: dangerous, Personal Protective Equipment for eyes and skin must be worn within the nominal hazard zone. Class 4 lasers are fire hazards as well. Diffuse reflections may be hazardous. Those lasers are commonly used for cutting or welding. This can create hazardous fumes. Cutting lasers generally create a small plasma which in turn emits UV light. UV light is another hazard to consider on a manufacturing floor.
• Type of laser: high power lasers.
• Maximum Permissible Exposure: ocular and skin MPE are exceeded. Diffuse reflections exceed the Minimal Permissible Exposure.
• Nominal Hazard Zone: hazard area for the eye and for the skin.
• Typical Accessible Emission Limit*: no limit.

Notes

Accessible Emission Limit (AEL): an AEL is the maximum value of accessible laser radiation to which an individual could be exposed during the operation of a laser and is dependent on the laser class. The AEL above are given as an indication for continuous lasers, but may change for pulsed lasers or infrared lasers.

Optical instruments: two types of optical instruments increase the hazard of M lasers:

• instruments which will reduce the diameter of a collimated beam (telescopes, beam reducers, binoculars). This is dangerous when using lasers with large beams (>7mm) since it is likely to increase the amount of light entering the pupil of the eye.
• Converging optics such as lenses, loupes, prescription eyewear… this is an increased hazard when using highly divergent beams since it will make it less divergent for the eye, allowing a greater amount of light to enter the eye.

The short answer is yes, but so are chainsaws, welders and cars. If they were totally safe they wouldn’t be as useful as they are. Yes lasers can create a small explosion inside one’s head, and this is not an overstatement: a high power laser hitting the eye will be focused on the retina and vaporize tissues there, or even create a small hot plasma which will brutally expand. “Medium” power lasers will heat the retina, destroy retinal receptors, puncture blood vessels, induce haemorrhages inside the eyes… and the worst thing is that you wouldn’t notice it until it’s way too late.

As a small comparison, the energy level passing through the pupil of the eye when looking directly at a 2 mW HeNe laser is of similar level to the one when looking directly at the midday sun under the tropics by cloudless weather. Except that the image of the sun inside the eye is more widespread. The laser light on the other hand is collimated out of the laser and will image as a very small spot on the retina (10-20µm). In those conditions, it is easy to reach power densities as high as a few thousands of W/cm². Keep in mind that generally speaking, fire hazard ^[1] starts at 10 W/cm². What happens inside one’s eye when looking directly at a laser is exactly the same as when using a magnifying glass to focus the sunlight over some delicate paper.

Here is another example: consider a 2 W, 532 nm pulsed DPSS laser with a pulse width of 1 ns and repetition rate of 20 Hz. Nothing fancy, this level of power is quite common in the industry. This laser’s diffuse reflection (on a chair frame or optical mount for instance) can blind someone 10 km away. And that is only due to indirect viewing.

Accidents can be avoided by a few simple policies:

• Hire a professional to assess the safety of your laser lab or factory.
• NEVER, EVER LOOK DIRECTLY INTO A LASER BEAM, even if you think it’s safe and even if you wear laser protection goggles.
• Work in a windowless room or seal off windows with certified laser barriers or curtains.
• No one should be allowed in the laser room without wearing proper protective eyewear, certified and rated against your laser specifications.
• Keep track of your beam path and cut off all beams with beam dumps where appropriate.
• Establish a protocol for entering or exiting the laser room. This will include a laser hazard warning sign, ideally a doorbell, an interlock, emergency shut-off button and a warning light.
• Reduce the power of your laser when aligning it.
• Remove chairs and stools from the surrounding of your laser table, to prevent people sitting around it (which would place their eyes at beam level).
• Remember that even diffuse reflectance (or reflectance of reflected light) from a class IV laser can be dangerous. This include reflectance on optical mounts, the table itself or even the floor

This is by no mean an exhaustive list. Common sense must rule, be aware of the dangers at all time and never underestimate them.

Reference
1. Section 7.2.3 of the ANSI Z136.1-2007