Tilted Wave Interferometry(TWI)is a measurement technique for fast and flexible interferometric testing of aspheres and freeform surfaces.The first version of the tilted wave principle was implemented in a Twyman-Gree...Tilted Wave Interferometry(TWI)is a measurement technique for fast and flexible interferometric testing of aspheres and freeform surfaces.The first version of the tilted wave principle was implemented in a Twyman-Green type setup with separate reference arm,which is intrinsically susceptible to environmentally induced phase disturbances.In this contribution we present the TWI in a new robust common-path(Fizeau)configuration.The implementation of the Tilted Wave Fizeau Interferometer requires a new approach in illumination,calibration and evaluation.Measurements of two aspheres and a freeform surface show the flexibility and also the increased stability in both phase raw data and surface measurements,which leads to a reduced repeatability up to a factor of three.The novel configuration significantly relaxes the tolerances of the imaging optics used in the interferometer.We demonstrate this using simulations on calibration measurements,where we see an improvement of one order of magnitude compared to the classical Twyman-Green TWI approach and the capability to compensate higher order error contributions on the used optics.展开更多
文摘Tilted Wave Interferometry(TWI)is a measurement technique for fast and flexible interferometric testing of aspheres and freeform surfaces.The first version of the tilted wave principle was implemented in a Twyman-Green type setup with separate reference arm,which is intrinsically susceptible to environmentally induced phase disturbances.In this contribution we present the TWI in a new robust common-path(Fizeau)configuration.The implementation of the Tilted Wave Fizeau Interferometer requires a new approach in illumination,calibration and evaluation.Measurements of two aspheres and a freeform surface show the flexibility and also the increased stability in both phase raw data and surface measurements,which leads to a reduced repeatability up to a factor of three.The novel configuration significantly relaxes the tolerances of the imaging optics used in the interferometer.We demonstrate this using simulations on calibration measurements,where we see an improvement of one order of magnitude compared to the classical Twyman-Green TWI approach and the capability to compensate higher order error contributions on the used optics.
