A pyranometer is a specialized radiometer that quantifies hemispherical solar irradiance—capturing both direct beam and diffuse sky radiation across a 180° field of view—via a thermopile’s thermoelectric conversion of absorbed shortwave energy (0.3–3 μm) into a precise electrical output proportional to flux density in W/m².

EKO Instruments offers high-precision pyranometers models compliant with ISO 9060 standards. 

2. What is a pyranometer used for?

A pyranometer is used to measure how much solar energy reaches the Earth’s surface.

In simple terms, it tells you how strong the sunlight is at a given location. This information is essential for:

1. Evaluating solar panel performance
2. Estimating energy production at solar power plants
3. Studying weather and climate patterns
4. Monitoring sunlight for agriculture and environmental research

Think of a pyranometer as a sunlight meter—it helps engineers, scientists, and solar operators understand exactly how much usable solar energy is available, so systems can be designed, tested, and optimized with confidence.

3. What is the difference between pyrheliometer and pyranometer?

Both instruments measure sunlight, but they do it from very different perspectives—the Pyranometer looks at the whole sky, a pyrheliometer locks onto the sun itself.

A pyranometer measures the total solar energy falling on a surface. It captures not only the sunlight coming straight from the sun, but also the light scattered by clouds, air, and dust. With its dome-shaped sensor and wide view of the sky, it’s ideal for tracking global horizontal irradiance (GHI) and is widely used in solar PV monitoring, weather stations, and climate research.

A pyrheliometer, by contrast, is highly selective. It measures only the direct solar beam and ignores scattered light. Its narrow viewing tube must stay perfectly aligned with the sun, which is why it’s mounted on a Solar Sun tracker. This makes it essential for direct normal irradiance (DNI) measurements, especially in concentrated solar power (CSP) projects and precision solar resource studies.

4. Who invented the pyranometer?

The pyranometer wasn’t invented by a single person—it’s the result of several scientists building on each other’s work.

In 1893, Swedish physicist Anders Knutsson Ångström created one of the first instruments to measure total (global) solar radiation, laying the foundation.

So, rather than a single inventor, the pyranometer emerged through collaborative scientific progress in the early 20th century, evolving into the precise instruments used today.

EKO Instruments continues this legacy with advanced ISO 9060-compliant models using similar thermopile principles enhanced by quartz diffusers and smart diagnostics.

5. What is the difference between a pyranometer and a par sensor?

A pyranometer and a PAR sensor both respond to sunlight, but they answer different questions.

A pyranometer measures how much solar energy is arriving. It captures the entire solar spectrum (roughly 300–2800 nm) and reports the result as energy per area (W/m²). This makes it the essential instrument for solar power, weather monitoring, and climate studies, where the goal is to understand heat and energy from the sun.

A PAR sensor, on the other hand, measures how useful that light is for plants. It looks only at the narrow band of light plants use for photosynthesis (400–700 nm) and counts photons, not energy. Its output is PPFD (µmol/m²/s), which is why it’s essential in agriculture, greenhouses, and ecological research.

6. What is another name for a pyranometer?

A pyranometer is also referred to as:

Global radiation sensor

Solar radiation sensor

Solar energy flux meter (less common, more technical)

All of these terms describe the same core function of measuring the intensity of sunlight falling on a surface, typically expressed in watts per square meter (W/m²).

7. What is the life span of a pyranometer?

The lifespan of a pyranometer is typically between 10 and 20 years, and often longer, if it’s well maintained.

EKO pyranometers are backed by up to a 5-year manufacturer’s warranty.

8. How to calibrate a pyranometer?

Pyranometer calibration ensures measurement accuracy by comparing the test instrument against a reference standard under controlled conditions, ensuring the following ISO 17025 or ISO 9846/9847 standards. 

EKO Instruments offers professional calibration services, ISO/IEC17025-accredited recalibration for pyranometers, pyrheliometers, and viscometers, ensuring measurements meet international laboratory standards.

9. Where are pyranometers used?