Linear signal synthesis using the Radon-Wigner transform

“…The WD is reconstructed from the RWT using the inverse Radon transform. A good agreement between the RWTs and the WDs obtained experimentally [see Measuring the RWT allows the identification of the quadratic chirp components of signals [1], which is particularly relevant for the characterization of optical systems. The angle α corresponding to the intensity peak in the RWT indicates that the chirp exp½iπx 2 =ðλf c Þ has parameter f c ¼ −s 2 λ −1 tan α.…”

“…The set of the WD projections at an arbitrary angle in phase-space, known as a Radon-Wigner transform (RWT) [1], contains the same information about the signal as the WD. In contrast to the WD, the RWT takes only nonnegative values and, therefore, can be directly measured [2].…”

“…In the case of one-dimensional (1D) signals, the RWT is a two-dimensional (2D) function defined as Pðα; xÞ ¼ Z dqW ðx cos α − s 2 q sin α; q cos α þ s −2 x sin αÞ; ð1Þ where W ðx; qÞ ¼ R dx 0 Γðx þ x 0 =2; x − x 0 =2Þ expð−i2πx 0 qÞ is the WD of the signal, ðx; qÞ are the space and frequency coordinates, Γðx 1 ; x 2 Þ ¼ hf ðx 1 Þf à ðx 2 Þi is the mutual intensity of the signal f ð·Þ, and s is a normalization parameter with dimension of length that depends on the system implementation. The transformation angle α varies in a π interval.…”

Phase-space tomography with a programmable Radon–Wigner display

“…The WD is reconstructed from the RWT using the inverse Radon transform. A good agreement between the RWTs and the WDs obtained experimentally [see Measuring the RWT allows the identification of the quadratic chirp components of signals [1], which is particularly relevant for the characterization of optical systems. The angle α corresponding to the intensity peak in the RWT indicates that the chirp exp½iπx 2 =ðλf c Þ has parameter f c ¼ −s 2 λ −1 tan α.…”

“…The set of the WD projections at an arbitrary angle in phase-space, known as a Radon-Wigner transform (RWT) [1], contains the same information about the signal as the WD. In contrast to the WD, the RWT takes only nonnegative values and, therefore, can be directly measured [2].…”

“…In the case of one-dimensional (1D) signals, the RWT is a two-dimensional (2D) function defined as Pðα; xÞ ¼ Z dqW ðx cos α − s 2 q sin α; q cos α þ s −2 x sin αÞ; ð1Þ where W ðx; qÞ ¼ R dx 0 Γðx þ x 0 =2; x − x 0 =2Þ expð−i2πx 0 qÞ is the WD of the signal, ðx; qÞ are the space and frequency coordinates, Γðx 1 ; x 2 Þ ¼ hf ðx 1 Þf à ðx 2 Þi is the mutual intensity of the signal f ð·Þ, and s is a normalization parameter with dimension of length that depends on the system implementation. The transformation angle α varies in a π interval.…”

Phase-space tomography with a programmable Radon–Wigner display

“…2,34 This approach led to the development of a chart that contains a continuous representation of the FRT of a signal as a function of its fractional order. 35 This representation may also be useful in optics, since it explicitly shows the propagation of a signal inside a GRIN medium.…”

Wigner-related phase spaces for signal processing and their optical implementation

“…Recently, a new time-frequency analyzing tool, the Radon -Wigner transform, was suggested 2,3 and used for the time-frequency representation of signals. 4,5 Without being named, this approach led exactly to a chart that contains a continuous representation of the FRT of a signal as a function of the fractional Fourier order. As we mention below, we call this representation the ͑x, p͒ chart, and it may also be useful in optics because it explicitly shows the propagation of a signal inside a gradedindex (GRIN) medium.…”

New signal representation based on the fractional Fourier transform: definitions