signal-processing algorithm Search Results


system studio model-based signal processing algorithm design and analysis tool  (Synopsys Inc)
90
Synopsys Inc system studio model-based signal processing algorithm design and analysis tool
System Studio Model Based Signal Processing Algorithm Design And Analysis Tool, supplied by Synopsys Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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spw signal processing algorithm tool  (Synopsys Inc)
90
Synopsys Inc spw signal processing algorithm tool
Spw Signal Processing Algorithm Tool, supplied by Synopsys Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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signal processing algorithm for pulse identification, qualification, and quantification  (Nonin Inc)
90
Nonin Inc signal processing algorithm for pulse identification, qualification, and quantification
Signal Processing Algorithm For Pulse Identification, Qualification, And Quantification, supplied by Nonin Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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advanced signal processing algorithms, architectures, and implementations xvii  (Optics and Photonics)
90
Optics and Photonics advanced signal processing algorithms, architectures, and implementations xvii
Advanced Signal Processing Algorithms, Architectures, And Implementations Xvii, supplied by Optics and Photonics, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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qinetiq signal-processing algorithm  (Qinetiq Ltd)
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Qinetiq Ltd qinetiq signal-processing algorithm
Qinetiq Signal Processing Algorithm, supplied by Qinetiq Ltd, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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saf signal processing algorithm  (Decon Laboratories)
90
Decon Laboratories saf signal processing algorithm
Simulated waveforms at four different levels of local distortion parameter, σq, before (left column) and after (right column) accounting for <t>spatial</t> <t>averaging</t> effects due to reception by a membrane hydrophone with a geometrical sensitive element diameter of 500 μm (by application of the <t>SAF).</t> The source has a center frequency of 5 mHz, diameter of 19 mm, and a focal length of 38 mm. The nonlinearity index values were σq = 0.6, σm = 0.5, SI = 0.06 (top row), σq = 1.0, σm = 0.8, SI = 0.11 (second row), σq = 2.3, σm = 1.9, SI = 0.32 (third row), and σq = 4.6, σm = 3.9, SI = 0.45 (fourth row).
Saf Signal Processing Algorithm, supplied by Decon Laboratories, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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innovative signal processing algorithms for radar target detection and tracking  (Olon Ricerca Bioscience)
90
Olon Ricerca Bioscience innovative signal processing algorithms for radar target detection and tracking
Simulated waveforms at four different levels of local distortion parameter, σq, before (left column) and after (right column) accounting for <t>spatial</t> <t>averaging</t> effects due to reception by a membrane hydrophone with a geometrical sensitive element diameter of 500 μm (by application of the <t>SAF).</t> The source has a center frequency of 5 mHz, diameter of 19 mm, and a focal length of 38 mm. The nonlinearity index values were σq = 0.6, σm = 0.5, SI = 0.06 (top row), σq = 1.0, σm = 0.8, SI = 0.11 (second row), σq = 2.3, σm = 1.9, SI = 0.32 (third row), and σq = 4.6, σm = 3.9, SI = 0.45 (fourth row).
Innovative Signal Processing Algorithms For Radar Target Detection And Tracking, supplied by Olon Ricerca Bioscience, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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spotlight synthetic aperture radar signal processing algorithms  (Artech House Inc)
90
Artech House Inc spotlight synthetic aperture radar signal processing algorithms
Simulated waveforms at four different levels of local distortion parameter, σq, before (left column) and after (right column) accounting for <t>spatial</t> <t>averaging</t> effects due to reception by a membrane hydrophone with a geometrical sensitive element diameter of 500 μm (by application of the <t>SAF).</t> The source has a center frequency of 5 mHz, diameter of 19 mm, and a focal length of 38 mm. The nonlinearity index values were σq = 0.6, σm = 0.5, SI = 0.06 (top row), σq = 1.0, σm = 0.8, SI = 0.11 (second row), σq = 2.3, σm = 1.9, SI = 0.32 (third row), and σq = 4.6, σm = 3.9, SI = 0.45 (fourth row).
Spotlight Synthetic Aperture Radar Signal Processing Algorithms, supplied by Artech House Inc, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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adaptive filtering algorithms for digital communications and audio signal processing  (KU Leuven)
90
KU Leuven adaptive filtering algorithms for digital communications and audio signal processing
Simulated waveforms at four different levels of local distortion parameter, σq, before (left column) and after (right column) accounting for <t>spatial</t> <t>averaging</t> effects due to reception by a membrane hydrophone with a geometrical sensitive element diameter of 500 μm (by application of the <t>SAF).</t> The source has a center frequency of 5 mHz, diameter of 19 mm, and a focal length of 38 mm. The nonlinearity index values were σq = 0.6, σm = 0.5, SI = 0.06 (top row), σq = 1.0, σm = 0.8, SI = 0.11 (second row), σq = 2.3, σm = 1.9, SI = 0.32 (third row), and σq = 4.6, σm = 3.9, SI = 0.45 (fourth row).
Adaptive Filtering Algorithms For Digital Communications And Audio Signal Processing, supplied by KU Leuven, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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signal-processing algorithms  (New Brunswick Scientific)
90
New Brunswick Scientific signal-processing algorithms
Simulated waveforms at four different levels of local distortion parameter, σq, before (left column) and after (right column) accounting for <t>spatial</t> <t>averaging</t> effects due to reception by a membrane hydrophone with a geometrical sensitive element diameter of 500 μm (by application of the <t>SAF).</t> The source has a center frequency of 5 mHz, diameter of 19 mm, and a focal length of 38 mm. The nonlinearity index values were σq = 0.6, σm = 0.5, SI = 0.06 (top row), σq = 1.0, σm = 0.8, SI = 0.11 (second row), σq = 2.3, σm = 1.9, SI = 0.32 (third row), and σq = 4.6, σm = 3.9, SI = 0.45 (fourth row).
Signal Processing Algorithms, supplied by New Brunswick Scientific, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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signal processing algorithms lumipoint  (Boston Scientific Corporation)
90
Boston Scientific Corporation signal processing algorithms lumipoint
Simulated waveforms at four different levels of local distortion parameter, σq, before (left column) and after (right column) accounting for <t>spatial</t> <t>averaging</t> effects due to reception by a membrane hydrophone with a geometrical sensitive element diameter of 500 μm (by application of the <t>SAF).</t> The source has a center frequency of 5 mHz, diameter of 19 mm, and a focal length of 38 mm. The nonlinearity index values were σq = 0.6, σm = 0.5, SI = 0.06 (top row), σq = 1.0, σm = 0.8, SI = 0.11 (second row), σq = 2.3, σm = 1.9, SI = 0.32 (third row), and σq = 4.6, σm = 3.9, SI = 0.45 (fourth row).
Signal Processing Algorithms Lumipoint, supplied by Boston Scientific Corporation, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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a91-43222 synthesis of a systolic computer for realizing a spatial signal processing algorithm  (Sintez OAO)
90
Sintez OAO a91-43222 synthesis of a systolic computer for realizing a spatial signal processing algorithm
Simulated waveforms at four different levels of local distortion parameter, σq, before (left column) and after (right column) accounting for <t>spatial</t> <t>averaging</t> effects due to reception by a membrane hydrophone with a geometrical sensitive element diameter of 500 μm (by application of the <t>SAF).</t> The source has a center frequency of 5 mHz, diameter of 19 mm, and a focal length of 38 mm. The nonlinearity index values were σq = 0.6, σm = 0.5, SI = 0.06 (top row), σq = 1.0, σm = 0.8, SI = 0.11 (second row), σq = 2.3, σm = 1.9, SI = 0.32 (third row), and σq = 4.6, σm = 3.9, SI = 0.45 (fourth row).
A91 43222 Synthesis Of A Systolic Computer For Realizing A Spatial Signal Processing Algorithm, supplied by Sintez OAO, used in various techniques. Bioz Stars score: 90/100, based on 1 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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Image Search Results


Simulated waveforms at four different levels of local distortion parameter, σq, before (left column) and after (right column) accounting for spatial averaging effects due to reception by a membrane hydrophone with a geometrical sensitive element diameter of 500 μm (by application of the SAF). The source has a center frequency of 5 mHz, diameter of 19 mm, and a focal length of 38 mm. The nonlinearity index values were σq = 0.6, σm = 0.5, SI = 0.06 (top row), σq = 1.0, σm = 0.8, SI = 0.11 (second row), σq = 2.3, σm = 1.9, SI = 0.32 (third row), and σq = 4.6, σm = 3.9, SI = 0.45 (fourth row).

Journal: IEEE transactions on ultrasonics, ferroelectrics, and frequency control

Article Title: Correction for Hydrophone Spatial Averaging Artifacts for Circular Sources

doi: 10.1109/TUFFC.2020.3007808

Figure Lengend Snippet: Simulated waveforms at four different levels of local distortion parameter, σq, before (left column) and after (right column) accounting for spatial averaging effects due to reception by a membrane hydrophone with a geometrical sensitive element diameter of 500 μm (by application of the SAF). The source has a center frequency of 5 mHz, diameter of 19 mm, and a focal length of 38 mm. The nonlinearity index values were σq = 0.6, σm = 0.5, SI = 0.06 (top row), σq = 1.0, σm = 0.8, SI = 0.11 (second row), σq = 2.3, σm = 1.9, SI = 0.32 (third row), and σq = 4.6, σm = 3.9, SI = 0.45 (fourth row).

Article Snippet: Inverse filtering with the SAF (“Decon Sens + SAF”) significantly suppresses spatial averaging effects. shows that measurements made with the high-resolution HGL-0085 hydrophone ( d g = 85 μ m) that were not corrected for spatial averaging (“Raw RF” or “Decon Sens”) were consistent with the trends of measurements made with the membrane hydrophones that were corrected for spatial averaging (“Decon Sens + SAF”).

Techniques: Membrane

Effects of spatial averaging on measurements of peak compressional pressure (pc), peak rarefactional pressure (pr), and pulse intensity integral for the 25 transducer/hydrophone combinations. The plots show: 1) raw data (“Raw RF”); 2) data deconvolved for hydrophone sensitivity only (“Decon Sens”); and 3) data deconvolved for hydrophone sensitivity and inverse filtered using Sp(nf1) over all harmonics with sufficient SNR (see Fig. 8) (“Decons Sens + SAF”). Data are plotted as a function of hydrophone nominal geometric sensitive element diameter, dg. Error bars (which are so small they are difficult to discern) denote standard deviations. Linear and exponential fits to data are also shown.

Journal: IEEE transactions on ultrasonics, ferroelectrics, and frequency control

Article Title: Correction for Hydrophone Spatial Averaging Artifacts for Circular Sources

doi: 10.1109/TUFFC.2020.3007808

Figure Lengend Snippet: Effects of spatial averaging on measurements of peak compressional pressure (pc), peak rarefactional pressure (pr), and pulse intensity integral for the 25 transducer/hydrophone combinations. The plots show: 1) raw data (“Raw RF”); 2) data deconvolved for hydrophone sensitivity only (“Decon Sens”); and 3) data deconvolved for hydrophone sensitivity and inverse filtered using Sp(nf1) over all harmonics with sufficient SNR (see Fig. 8) (“Decons Sens + SAF”). Data are plotted as a function of hydrophone nominal geometric sensitive element diameter, dg. Error bars (which are so small they are difficult to discern) denote standard deviations. Linear and exponential fits to data are also shown.

Article Snippet: Inverse filtering with the SAF (“Decon Sens + SAF”) significantly suppresses spatial averaging effects. shows that measurements made with the high-resolution HGL-0085 hydrophone ( d g = 85 μ m) that were not corrected for spatial averaging (“Raw RF” or “Decon Sens”) were consistent with the trends of measurements made with the membrane hydrophones that were corrected for spatial averaging (“Decon Sens + SAF”).

Techniques:

Membrane hydrophone simulation results (open circles and squares) for percent error in estimates of peak compressional pressure (pc), peak rarefactional pressure (pr), and pulse intensity integral, when: 1) no spatial averaging correction is applied (“Without SAF”) and 2) the full SAF inverse filter correction is applied (“With SAF”). Measurements are shown in asterisks and x’s. All simulation and experimental data were inverse filtered to deconvolve the effects of hydrophone frequency-dependent sensitivity. Simulation data without SAF are fit to functions of the form – 100% × [1 − exp(−αx)], where x = dg/(λ1F#) and α is a fitting parameter. Standard deviations for measurements are less than 1%.

Journal: IEEE transactions on ultrasonics, ferroelectrics, and frequency control

Article Title: Correction for Hydrophone Spatial Averaging Artifacts for Circular Sources

doi: 10.1109/TUFFC.2020.3007808

Figure Lengend Snippet: Membrane hydrophone simulation results (open circles and squares) for percent error in estimates of peak compressional pressure (pc), peak rarefactional pressure (pr), and pulse intensity integral, when: 1) no spatial averaging correction is applied (“Without SAF”) and 2) the full SAF inverse filter correction is applied (“With SAF”). Measurements are shown in asterisks and x’s. All simulation and experimental data were inverse filtered to deconvolve the effects of hydrophone frequency-dependent sensitivity. Simulation data without SAF are fit to functions of the form – 100% × [1 − exp(−αx)], where x = dg/(λ1F#) and α is a fitting parameter. Standard deviations for measurements are less than 1%.

Article Snippet: Inverse filtering with the SAF (“Decon Sens + SAF”) significantly suppresses spatial averaging effects. shows that measurements made with the high-resolution HGL-0085 hydrophone ( d g = 85 μ m) that were not corrected for spatial averaging (“Raw RF” or “Decon Sens”) were consistent with the trends of measurements made with the membrane hydrophones that were corrected for spatial averaging (“Decon Sens + SAF”).

Techniques: Membrane

Needle/fiber optic hydrophone simulation results (open circles and squares) for percent error in estimates of peak compressional pressure (pc), peak rarefactional pressure (pr), and pulse intensity integral, when: 1) no spatial averaging correction is applied (“Without SAF”) and 2) the full SAF inverse filter correction is applied (“With SAF”). All simulation data were inverse filtered to deconvolve the effects of hydrophone frequency-dependent sensitivity. Simulation data without SAF are fit to functions of the form −100% × [1 − exp(−βx2)], where x = dg/(λ1F#) and β is a fitting parameter.

Journal: IEEE transactions on ultrasonics, ferroelectrics, and frequency control

Article Title: Correction for Hydrophone Spatial Averaging Artifacts for Circular Sources

doi: 10.1109/TUFFC.2020.3007808

Figure Lengend Snippet: Needle/fiber optic hydrophone simulation results (open circles and squares) for percent error in estimates of peak compressional pressure (pc), peak rarefactional pressure (pr), and pulse intensity integral, when: 1) no spatial averaging correction is applied (“Without SAF”) and 2) the full SAF inverse filter correction is applied (“With SAF”). All simulation data were inverse filtered to deconvolve the effects of hydrophone frequency-dependent sensitivity. Simulation data without SAF are fit to functions of the form −100% × [1 − exp(−βx2)], where x = dg/(λ1F#) and β is a fitting parameter.

Article Snippet: Inverse filtering with the SAF (“Decon Sens + SAF”) significantly suppresses spatial averaging effects. shows that measurements made with the high-resolution HGL-0085 hydrophone ( d g = 85 μ m) that were not corrected for spatial averaging (“Raw RF” or “Decon Sens”) were consistent with the trends of measurements made with the membrane hydrophones that were corrected for spatial averaging (“Decon Sens + SAF”).

Techniques: