What Is the Difference Between Radiometers, Spectrometers, Spectroradiometers, and Spectrophotometers?

If you work in the biopharmaceutical industry, you’re likely familiar with the concept of light and color measurement and the equipment used in these processes — radiometers, spectrometers, spectroradiometers, and spectrophotometers. While all four solutions are used to detect light and energy, they vary widely in their capabilities, applications, and intended purposes. It’s important to know and understand the differences between these solutions to determine which one will adequately serve your needs.

Radiometer vs. Spectrometer vs. Spectroradiometer vs. Spectrophotometer

These devices have similar names and are used to measure spectral data points and wavelengths within the electromagnetic spectrum. Despite this similarity, they have varying scopes regarding the types and qualities of measurements they produce.

Radiometers can only detect and measure electromagnetic radiation within a particular wavelength range. Spectrometers measure a broader scale of electromagnetic energy and have more capabilities, including breaking down signals based on amplitude.

In comparing spectroradiometers vs. spectrometers, the main difference is that spectroradiometers combine the capabilities of radiometers and spectrometers. These devices also collect details about power, radiance, and other metrics.

Spectrophotometers measure light reflected or transmitted by objects, while radiometers measure light emitted by a light source. Unlike the other tools, spectrophotometers focus on how transmitted and reflected light generates color rather than on the qualities of the light itself.

What Is a Radiometer?

A radiometer measures the electromagnetic energy present in a specific wavelength range. This solution is typically used to detect and quantify energy outside the visible light spectrum and measure infrared and ultraviolet light. The radiometer begins by measuring the incoming current or voltage in watts, then corrects the signal to create a calibrated, quantitative light level measurement. With this information, the meter provides one reading over the specific wavelength range it is designed to measure.

Pros and Cons of Radiometers

Radiometers are inexpensive and portable, making them a cost-effective and practical choice. This solution can identify troublesome UV energy and detect and measure heat energy on surfaces. It also has one sensor that allows it to quickly measure all intended wavelengths.

However, radiometers cannot identify emitted wavelengths or their individual amplitude. Sometimes, variations exist in the filter used to match the light source, which creates difficulty when comparing results from radiometers of different manufacturers. Also, radiometers only measure a particular range of wavelengths, unlike other tools. 

Applications

Radiometers' ability to detect the presence of UV energy makes them valuable tools for any application where it is undesirable, such as museum lighting. In this atmosphere, UV energy could degrade artifacts or artwork.

The device also measures infrared light, enabling surface temperature measurements in settings such as along an assembly line or on a road's surface. Other applications include monitoring weather, like precipitation and wind speeds.

What Is a Spectrometer?

Spectrometers detect and measure wavelengths using numerous sensors and an optical grating or prism to break down the energy into components. Like a camera, spectrometers take a snapshot of the light and create an image or graph depicting the output to provide details about the light's qualities. They let in the light, break down the signal, and spread it across a sensor range. This sensor separates the wavelengths and scales them based on incoming signal amplitude and sensor sensitivity, resulting in quantitative measurements.

Spectrometers function like radiometers in that they measure wavelengths. However, spectrometers can separate incoming energy while radiometers can't. The difference between spectrometers vs. spectrophotometers is that a spectrometer is a general term used for devices that separate and measure spectral components. Spectrophotometers incorporate spectrometers in their design to undertake more specific functions.

Pros and Cons of Spectrometers

Spectrometers are highly precise, accurate, and analytical due to their thousands of sensors, and they are adaptable for use in many applications and industries. However, when the signal is weak, spectrometers may have issues with stray light or noise. Additionally, many spectrometers are not stand-alone tools and may require additional optics to work properly.

Applications

Spectrometers' uses vary widely because they require additional tools to function. In general, they work in applications requiring wavelength or energy information. These range from monitoring marine ecosystems to supporting space exploration. Other applications include characterizing proteins and analyzing respiratory gas in hospitals.

What Is a Spectroradiometer?

Spectroradiometers use light intensity calibration to measure luminance, precision radiance, and chromaticity. These tools are like a combined spectrometer and radiometer, with calibrations and optics that allow them to take calibrated measures of intensity, power, radiance, and irradiance. 

Pros and Cons of Spectroradiometers

There are far more pros of spectroradiometers than cons. They are highly accurate, portable, and act as stand-alone systems that do not need to be connected to a PC. Some can provide accurate data even in harsh conditions.

Applications

This type of solution is often used in research and development laboratories across chemical and physical sciences as a reference tool. It also evaluates a sample's visual qualities and can help support safety through applications like light fixture testing.

What Is a Spectrophotometer?

Spectrophotometers quantitatively measure transmission or reflectance properties as a function of wavelength, which allows the identification of colors.

When considering the difference between spectrometers and spectrophotometers, note that spectrophotometers contain a spectrometer but also use their own light source and all spectral components within a single unit. The purpose of spectrophotometers is to quickly detect the color of light a material emits and quantify it according to an accepted color model.

Pros and Cons of Spectrophotometers

Spectrophotometers have high sensitivity and throughput and are less complicated and more affordable than other solutions. However, they have drift problems due to the time needed between two events. This is corrected through regular instrument standardization and calibration.

Applications

Spectrophotometers can measure the concentration of a solution, determine the color of liquid and solid matter, and identify organic compounds. These capabilities enable the use of spectrophotometers across industries such as food manufacturing and processing, plastics, and chemicals.

Their quantitative and qualitative measurements provide information about how light is perceived as color. This capability makes spectrophotometers useful for regulatory and industry standards conformance, quality control, and identifying metamerism while eliminating human error.

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