Optical Metrology
- Chromatic Sensors
- Displacement Gages
- Ellipsometers
- Interferometers
- Laser Vibrometers
- Optical Frequency Combs
- Optical Surface Profilers
- Polarimeters
- Refractometers
- Strain Gages
- Thickness Measuring Systems
- Wavelength Meters
- Metrology Accessories
- Laser Micrometers
- Shearography Systems
- Scatterometers
- Video Micrometers
- Laser Gyroscopes
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Laser Vibrometers
Frequently Asked Questions
A laser vibrometer is an optical metrology tool that measures the velocity and displacement of surfaces with high precision and accuracy. It is commonly used in industries such as automotive, aerospace, and electronics for vibration analysis and product testing.
Laser vibrometers work by emitting a laser beam onto a surface and then measuring the frequency shift of the reflected light caused by the surface's motion. The frequency shift is proportional to the surface velocity or displacement, allowing for high-precision measurement of vibration and displacement.
Laser vibrometers offer non-contact, non-intrusive, and non-destructive measurement of vibrations, making them ideal for measuring delicate or fragile surfaces. They are also highly accurate and precise, with the ability to measure vibrations at frequencies ranging from DC to several MHz. Additionally, laser vibrometers can measure vibrations over long distances and in harsh environments, such as high temperatures or vacuum conditions.
Laser vibrometers are used in various industries, including automotive, aerospace, electronics, and acoustic engineering, for vibration analysis and product testing. They are commonly used for measuring vibration and displacement of structures, such as engine components, aircraft wings, and electronic circuits. Laser vibrometers can also be used for modal analysis, noise and vibration control, and quality control of products.
When choosing a laser vibrometer, it is important to consider factors such as measurement range, frequency range, sensitivity, and compatibility with the materials being measured. It is also important to consider the sample stage, which should be compatible with the sample being measured and provide stable support during measurement. Some laser vibrometers also offer additional features, such as automated data acquisition and analysis software.
Scanning laser vibrometers are capable of measuring vibrations over a wide area by scanning a laser beam across the surface, while single-point laser vibrometers measure vibrations at a specific point on the surface. Scanning laser vibrometers are useful for measuring vibration patterns and modal analysis of structures, while single-point laser vibrometers are suitable for measuring vibrations at specific points or on small structures.
Laser vibrometers have some limitations, such as sensitivity to environmental factors such as air turbulence, temperature changes, and noise. To overcome these limitations, laser vibrometers can be equipped with environmental controls, such as vibration isolation and temperature stabilization. Additionally, laser vibrometers may have limited measurement ranges or may require specialized sample stages for specific applications. It is important to choose a laser vibrometer that is suited for the specific application and that can provide the required accuracy and precision.
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