Passive translational velocity measurement from optical information
First Claim
1. A method for determining a linear speed (Δ
- v) of an object, comprising the steps of;
a) sampling a series of light intensity courses I(t) over time t, each light intensity courses I(t) covering a different azimuthal direction, each different azimuthal direction defining a detection length (λ
i;
i=1, . . . , k) of a series of detection lengths (λ
i) as seen in a direction of the linear speed (Δ
v) to be determined;
b) transforming the series of detection lengths (λ
i) for the azimuthal directions into a series of linear spatial frequencies (SFi);
c) defining for each azimuthal direction a band pass or a high pass filter, relating for each detection length (λ
i) characteristic filter frequencies to respective linear spatial frequencies (SFi);
d) filtering sampled light intensity for each azimuthal direction with the respective band pass or high pass filter to obtain a set of filtered light intensities;
e) calculating the linear speed by dividing the characteristic filter frequencies through the linear spatial frequencies (SFi) for at least one of azimuthal directions for which the filtered light intensity exceeds a predefined threshold; and
f) determining the linear speed by correlating the calculated linear speeds for those azimuthal directions for which the filtered light intensity exceeds a predefined threshold.
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Abstract
The invention is a passive method to measure the translational speed of a visual scene using the distribution of light intensities. The invention combines two principles: perspective distortion matching over a broad field of view, and temporal filtering variation. The perspective distortion of the image is used to sample the visual scene at different linear wavelengths over the visual field. The result is a spatial sensitivity map of the visual scene. The obtained signal is then temporally filtered with cutoff frequencies proportional to the spatial sensitivity. The final result is a wide-spectrum computation of a ratio between temporal and linear spatial frequencies, in other words linear speed. The technique does not require the emission of a reference signal and is independent from external infrastructures.
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Citations
4 Claims
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1. A method for determining a linear speed (Δ
- v) of an object, comprising the steps of;
a) sampling a series of light intensity courses I(t) over time t, each light intensity courses I(t) covering a different azimuthal direction, each different azimuthal direction defining a detection length (λ
i;
i=1, . . . , k) of a series of detection lengths (λ
i) as seen in a direction of the linear speed (Δ
v) to be determined;b) transforming the series of detection lengths (λ
i) for the azimuthal directions into a series of linear spatial frequencies (SFi);c) defining for each azimuthal direction a band pass or a high pass filter, relating for each detection length (λ
i) characteristic filter frequencies to respective linear spatial frequencies (SFi);d) filtering sampled light intensity for each azimuthal direction with the respective band pass or high pass filter to obtain a set of filtered light intensities; e) calculating the linear speed by dividing the characteristic filter frequencies through the linear spatial frequencies (SFi) for at least one of azimuthal directions for which the filtered light intensity exceeds a predefined threshold; and f) determining the linear speed by correlating the calculated linear speeds for those azimuthal directions for which the filtered light intensity exceeds a predefined threshold. - View Dependent Claims (2, 3)
- v) of an object, comprising the steps of;
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4. A system for determining a linear speed (Δ
- v) of an object, comprising;
a) a set of photoreceptors disposed on the object, composed of subsets of 3 photoreceptors, said subset of photoreceptors (35i, o1, o2, o3) measuring light intensities I(t) and being arranged to cover identical angular apertures pointing in different azimuthal directions, each different azimuthal direction defines a detection length (λ
i;
i=1, . . . , k) of a series of detection lengths (λ
) as seen in a direction of the linear speed (Δ
v) to be determined;b) means (C) for calculation the linear speed (Δ
v) for evaluation subsets (36j;
j=1, . . . , k−
1), each evaluation subset (36j) comprising the intensity inputs of three adjacent photoreceptors (o1, o2, o3), by performing for at least part of the subsets (36j);c) subtracting the light intensities inputs from two extreme photoreceptors (o1, o3) of each evaluation subset (36j) to receive a first difference signal (s13); d) splitting the first difference signal (s13) on two lines, one line delaying the difference signal (s13) by a temporal delay (τ
);e) subtracting the signals (s13, delayed s13) from the two lines to receive a second difference signal (ts13); and f) multiplying the second difference signal (ts13) with the input from a central photoreceptor (o2) to achieve an output signal (sso) being indicative for the linear speed (Δ
v).
- v) of an object, comprising;
Specification