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摘要

The imaging apparatus includes an image sensor circuit comprising a time of flight sensor pixel. The imaging apparatus further includes a first light emitter having a first spatial offset relative to the time of flight sensor pixel. The imaging apparatus further includes a second light emitter having a second spatial offset relative to the time of flight sensor pixel. The imaging apparatus further includes an image processing circuit configured to produce an image of a region of an object based on first sensor pixel image data and second sensor pixel image data generated by the time of flight sensor pixel. The first sensor pixel image data is based on received light emitted by the first light emitter and reflected at the object's region and wherein the second sensor pixel image data is based on received light emitted by the second light emitter and reflected at the object's region.

說明書

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RELATED APPLICATION

This application claims priority under 35 U.S.C. § 119 to German Patent Application No. 102014115310.3, filed on Oct. 21, 2014, the content of which is incorporated by reference herein in its entirety.

TECHNICAL FIELD

Embodiments relate to producing three-dimensional images and in particular to imaging apparatuses and a time of flight imaging method.

BACKGROUND

Time of flight (TOF) systems are based on three-dimensional (3D) image sensor principles. Pixels may be more complex compared to pixels of a two-dimensional (2D) imager, for example. Pixels may be larger, for example. A high resolution imager may require large chip area, large optics and a large volume camera, for example. This may result in high or increased costs, for example.

SUMMARY

權(quán)利要求

1

The invention claimed is:

1. An imaging apparatus, comprising:an image sensor circuit comprising a time of flight sensor pixel;

a first light emitter having a first spatial offset relative to the time of flight sensor pixel;

a second light emitter having a second spatial offset relative to the time of flight sensor pixel; and

an image processing circuit configured to produce an image of a region of an object based on first sensor pixel image data and second sensor pixel image data generated by the time of flight sensor pixel,

wherein the first sensor pixel image data is based on received light emitted by the first light emitter and reflected at the region of the object and wherein the second sensor pixel image data is based on received light emitted by the second light emitter and reflected at the region of the object,

wherein the image processing circuit is configured to determine first sub-image data of a first sub-region of the region of the object and second sub-image data of a second sub-region of the region of the object, and

wherein the image processing circuit is configured to determine the first sub-image data based on a first linear combination of phase-shifted versions of the first sensor pixel image data and the second sensor pixel image data and to determine the second sub-image data based on a second linear combination of phase-shifted versions of the first sensor pixel image data and the second sensor pixel image data.

2. The imaging apparatus of claim 1, wherein the first light emitter and the second light emitter are arranged at different equidistant positions relative to the image sensor circuit.

3. The imaging apparatus of claim 1, wherein the first light emitter and the second light emitter are arranged symmetrically with respect to at least one axis of symmetry of the image sensor circuit.

4. The imaging apparatus of claim 1, wherein the first light emitter is configured to emit light during a first time interval and the second light emitter is configured to emit light during a second time interval.

5. The imaging apparatus of claim 1, wherein the first light emitter and the second light emitter are configured to simultaneously emit differently polarized light.

6. The imaging apparatus of claim 1, wherein the time of flight sensor pixel comprises a photonic mixing device configured to generate the first sensor pixel image data and the second sensor pixel image data based on a respective cross-correlation measurement based on received modulated light and a reference modulation signal.

7. The imaging apparatus of claim 1, wherein the first light emitter and the second light emitter respectively comprise a light emitting portion of a light transmitter.

8. The imaging apparatus of claim 1, wherein the first light emitter and the second light emitter respectively comprises one or more light emitting diodes or lasers.

9. The imaging apparatus of claim 1, wherein a number of sub-regions corresponds to a number of light emitters having different spatial offsets.

10. The imaging apparatus of claim 1, wherein the image processing circuit is configured to produce the first sub-image data and the second sub-image data based on a linear combination of phase-shifted versions of the first sensor pixel image data and the second sensor pixel image data.

11. The imaging apparatus of claim 1, wherein the image processing circuit is configured to obtain the phase-shifted versions of the first sensor pixel image data and the second sensor pixel image data based on a combination of the first sensor pixel image data and the second sensor pixel image data with a set of time of flight offsets, wherein a first time of flight offset, of the set of time of flight offsets, is associated with the first light emitter and the first sub-region, a second time of flight offset, of the set of time of flight offsets, is associated with the first light emitter and the second sub-region, a third time of flight offset, of the set of time of flight offsets, is associated with the second light emitter and the first sub-region, and a fourth time of flight offset, of the set of time of flight offsets, is associated with the second light emitter and the second sub-region.

12. The imaging apparatus of claim 11, whereinthe first time of flight offset denotes an offset between a reference time of flight of received light emitted by a reference light emitter and reflected at the first sub-region and a time of flight of received light emitted by the first light emitter and reflected at the first sub-region,

the second time of flight offset denotes an offset between a reference time of flight of received light emitted by the reference light emitter and reflected at the second sub-region and a time of flight of received light emitted by the first light emitter and reflected at the second sub-region,

the third time of flight offset denotes an offset between the reference time of flight of received light emitted by the reference light emitter and reflected at the first sub-region and a time of flight of received light emitted by the second light emitter and reflected at the first sub-region, and

the fourth time of flight offset denotes an offset between the reference time of flight of received light emitted by the reference light emitter and reflected at the second sub-region and a time of flight of received light emitted by the second light emitter and reflected at the second sub-region.

13. The imaging apparatus of claim 11, wherein the image processing circuit is configured to determine the first sub-image data and the second sub-image data corresponding to

(\begin{matrix} \underline{Z_{a}} \\ \underline{Z_{b}} \end{matrix}) = φ_{delay}^{- 1} \cdot (\begin{matrix} \underline{Z_{meas ? ? 1}} \\ \underline{Z_{meas ? ? 2}} \end{matrix}), ? wherein

φ_{delay} = (\begin{matrix} e^{j ? ? Δ ? ? φ_{a ? ? 1}} & e^{j ? ? Δ ? ? φ_{b ? ? 1}} \\ e^{j ? ? Δ ? ? φ_{a ? ? 2}} & e^{j ? ? Δ ? ? φ_{b ? ? 2}} \end{matrix}),

wherein Z_aand Z_bcomprise intensity and phase information related to the first sub-image data and the second sub-image data respectively, wherein Z_meas1 and Z_meas2 comprise intensity and phase information related to the first sensor pixel image data and the second sensor pixel image data respectively, and wherein e^jΔφ^a1, e^jΔφ^b1, e^jΔφ^a2, and e^jΔφ^b1are indicative of the first time of flight offset, the second time of flight offset, the third time of flight offset, and the fourth time of flight offset, respectively.

14. The imaging apparatus of claim 1, wherein the image processing circuit is configured to produce the image of the region of the object based on a comparison of phase information of the first sensor pixel image data and the second sensor pixel image data.

15. The imaging apparatus of claim 14, wherein the image processing circuit is configured to produce the image of the region of the object based on a selection of one of the first sensor pixel image data or the second sensor pixel image data having a smallest phase value.

16. A time of flight imaging method, the method comprising:receiving, by a time of flight sensor pixel, light emitted by a first light emitter having a first spatial offset relative to the time of flight sensor pixel and reflected by a region of an object to generate first sensor pixel image data;

receiving, by the time of flight sensor pixel, light emitted by a second light emitter having a second spatial offset relative to the time of flight sensor pixel and reflected by the region of the object to generate second sensor pixel image data; and

producing an image of the region of the object based on the first sensor pixel image data and the second sensor pixel image data generated by the time of flight sensor pixel,

wherein producing the image is based on determining a first sub-image data of a first sub-region of the region of the object and second sub-image data of a second sub-region of the region of the object, and

wherein determining the first sub-image data is based on a first linear combination of phase-shifted versions of the first sensor pixel image data and the second sensor pixel image data; and

wherein determining the second sub-image data is based on a second linear combination of phase-shifted versions of the first sensor pixel image data and the second sensor pixel image data.

17. The method of claim 16,wherein a number of sub-regions corresponds to a number of light emitters having different spatial offsets, wherein the first sub-image data and the second sub-image data are determined based on the first sensor pixel image data and the second sensor pixel image data.

18. The method of claim 17,wherein the phase-shifted versions of the first sensor pixel image data and the second sensor pixel image data are obtained based on a combination of the first sensor pixel image data and the second sensor pixel image data with a set of time of flight offsets, wherein a first time of flight offset, of the set of time of flight offsets, is associated with the first light emitter and the first sub-region, a second time of flight offset, of the set of time of flight offsets, is associated with the first light emitter and the second sub-region, a third time of flight offset, of the set of time of flight offsets, is associated with the second light emitter and the first sub-region, and a fourth time of flight offset, of the set of time of flight offsets, is associated with the second light emitter and the second sub-region.

19. An imaging apparatus, comprising:an image sensor circuit comprising a plurality of time of flight sensor pixels;

a first light emitter having a first spatial offset relative to the image sensor circuit;

a second light emitter having a second spatial offset relative to the image sensor circuit; and

an image processing circuit configured to produce an image of a region of an object based on first sensor pixel image data and second sensor pixel image data generated by a time of flight sensor pixel of the plurality of time of flight sensor pixels, wherein the image comprises first sub-image data of a first sub-region of the object and second sub-image data about a second sub-region of the object,

wherein the first sensor pixel image data is based on received light emitted by the first light emitter and reflected by the object and wherein the second sensor pixel image data is based on received light emitted by the second light emitter and reflected by the object,

wherein the image processing circuit is configured to obtain phase-shifted versions of the first sensor pixel image data and the second sensor pixel image data based on a combination of the first sensor pixel image data and the second sensor pixel image data with a set of time of flight offsets, and

wherein a first time of flight offset, of the set of time of flight offsets, is associated with the first light emitter and the first sub-region, a second time of flight offset, of the set of time of flight offsets, is associated with the first light emitter and the second sub-region, a third time of flight offset, of the set of time of flight offsets, is associated with the second light emitter and the first sub-region, and a fourth time of flight offset, of the set of time of flight offsets, is associated with the second light emitter and the second sub-region.

20. The imaging apparatus of claim 19, wherein the plurality of time of flight sensor pixels include a planar surface, andwherein the first light emitter and the second light emitter are arranged coplanar to the planar surface of the plurality of time of flight sensor pixels.

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Imaging apparatuses and a time of flight imaging method

摘要

說明書

權(quán)利要求

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Imaging apparatuses and a time of flight imaging method

摘要

說明書

權(quán)利要求

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