FOURIER TRANSFORM PROFILOMETRY WITH A DUAL READOUT SENSOR

Organization Name

meta platforms technologies, llc

Inventor(s)

Song Chen of Redmond WA (US)

Qing Chao of Redmond WA (US)

Yi Zheng of Redmond WA (US)

FOURIER TRANSFORM PROFILOMETRY WITH A DUAL READOUT SENSOR - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240340404 titled 'FOURIER TRANSFORM PROFILOMETRY WITH A DUAL READOUT SENSOR

Simplified Explanation

The patent application describes a system for three-dimensional object sensing using fringe-projection profilometry with Fourier transform analysis. This system projects frequency signal patterns onto an object's surface and captures reflections to generate a wrapped phase map for reconstructing the object's surface in 3D.

• Fringe-projection profilometry (FPP) projector transmits frequency and zero-frequency signal patterns onto the object's surface.
• Dual readout sensor captures reflections of both signals to extract an enhanced signal.
• Enhanced signal is used to generate a wrapped phase map through Fourier transform profilometry (FTP).
• Unwrapped phase map is used for three-dimensional reconstruction of the object's surface.

Key Features and Innovation

• Utilizes fringe-projection profilometry for object sensing.
• Incorporates Fourier transform analysis for accurate 3D reconstruction.
• Dual readout sensor enhances signal quality for better results.

Potential Applications

• Quality control in manufacturing for precise measurements.
• 3D scanning and modeling for virtual reality and augmented reality applications.
• Biomedical imaging for detailed anatomical scans.

Problems Solved

• Accurate and detailed 3D reconstruction of objects.
• Improved signal quality for better sensing results.
• Efficient and reliable object sensing technology.

Benefits

• High precision in 3D object reconstruction.
• Versatile applications in various industries.
• Enhanced signal quality for reliable results.

Commercial Applications

1. 1. 1. Fringe-projection profilometry for Advanced Object Sensing and Reconstruction

This technology can be applied in industries such as manufacturing, healthcare, and entertainment for precise measurements, detailed scans, and immersive experiences.

Prior Art

Further research can be conducted on existing fringe-projection profilometry systems and Fourier transform analysis techniques for object sensing and 3D reconstruction.

Frequently Updated Research

Stay updated on advancements in fringe-projection profilometry, Fourier transform analysis, and object sensing technologies for potential improvements in accuracy and efficiency.

Questions about Three-Dimensional Object Sensing

What are the potential limitations of fringe-projection profilometry in object sensing applications?

Fringe-projection profilometry may face challenges in dealing with complex surface geometries and reflective materials, which can affect the accuracy of 3D reconstructions.

How does Fourier transform analysis enhance the accuracy of 3D reconstructions in object sensing?

Fourier transform analysis helps in processing the captured signals to generate precise wrapped phase maps, which are crucial for accurate 3D reconstructions.

Original Abstract Submitted

a system for three-dimensional object sensing using fringe-projection profilometry with fourier transform analysis is described. a fringe-projection profilometry (fpp) projector simultaneously transmits a frequency signal pattern (i.e., modulated or ac signal) and a zero-frequency signal pattern (i.e., unmodulated or dc signal) onto an object's surface. alternatively, the projector projects two frequency signal patterns phase-shifted by 180 degrees. a dual readout sensor captures reflections of both signals from the object's surface as adjacent frames, and the dc signal is extracted by subtraction of addition to obtain an enhanced signal. the enhanced signal is used to generate a wrapped phase map through fourier transform profilometry (ftp). the resulting wrapped phase map is unwrapped, and three-dimensional reconstruction of the object's surface is generated by converting phase from the unwrapped phase map to three-dimensional coordinates.