Abstract: A pair of first gate electrodes IGR, IGL are provided on a semiconductor substrate 100 so that potentials ?TX1, ?TX2 between a light-sensitive area SA and a pair of first accumulation regions AR, AL alternately ramp. A pair of second gate electrodes IGR, IGL are provided on the semiconductor substrate 100 so as to control the height of first potential barriers ?BG each interposed between the first accumulation region AR, AL and a second accumulation region FDR, FDL, and increase the height of the first potential barrier ?BG to carriers as a higher output of a background light is detected by a photodetector.

Abstract: Two charge quantities (Q1,Q2) are output from respective pixels P (m,n) of the back-illuminated distance measuring sensor 1 as signals d?(m,n) having the distance information. Since the respective pixels P (m,n) output signals d?(m,n) responsive to the distance to an object H as micro distance measuring sensors, a distance image of the object can be obtained as an aggregate of distance information to respective points on the object H if reflection light from the object H is imaged on the pickup area 1B. If carriers generated at a deep portion in the semiconductor in response to incidence of near-infrared light for projection are led in a potential well provided in the vicinity of the carrier-generated position opposed to the light incident surface side, high-speed and accurate distance measurement is enabled.

Abstract: Two charge quantities (Q1,Q2) are output from respective pixels P (m,n) of the back-illuminated distance measuring sensor 1 as signals d?(m,n) having the distance information. Since the respective pixels P (m,n) output signals d?(m,n) responsive to the distance to an object H as micro distance measuring sensors, a distance image of the object can be obtained as an aggregate of distance information to respective points on the object H if reflection light from the object H is imaged on the pickup area 1B. If carriers generated at a deep portion in the semiconductor in response to incidence of near-infrared light for projection are led in a potential well provided in the vicinity of the carrier-generated position opposed to the light incident surface side, high-speed and accurate distance measurement is enabled.

Abstract: Two charge quantities (Q1,Q2) are output from respective pixels P (m,n) of the back-illuminated distance measuring sensor 1 as signals d?(m,n) having the distance information. Since the respective pixels P (m,n) output signals d?(m,n) responsive to the distance to an object H as micro distance measuring sensors, a distance image of the object can be obtained as an aggregate of distance information to respective points on the object H if reflection light from the object H is imaged on the pickup area 1B. If carriers generated at a deep portion in the semiconductor in response to incidence of near-infrared light for projection are led in a potential well provided in the vicinity of the carrier-generated position opposed to the light incident surface side, high-speed and accurate distance measurement is enabled.

Abstract: Two charge quantities (Q1,Q2) are output from respective pixels P (m,n) of the back-illuminated distance measuring sensor 1 as signals d?(m,n) having the distance information. Since the respective pixels P (m,n) output signals d?(m,n) responsive to the distance to an object H as micro distance measuring sensors, a distance image of the object can be obtained as an aggregate of distance information to respective points on the object H if reflection light from the object H is imaged on the pickup area 1B. If carriers generated at a deep portion in the semiconductor in response to incidence of near-infrared light for projection are led in a potential well provided in the vicinity of the carrier-generated position opposed to the light incident surface side, high-speed and accurate distance measurement is enabled.

Abstract: Two charge quantities (Q1,Q2) are output from respective pixels P (m,n) of the back-illuminated distance measuring sensor 1 as signals d?(m,n) having the distance information. Since the respective pixels P (m,n) output signals d?(m,n) responsive to the distance to an object H as micro distance measuring sensors, a distance image of the object can be obtained as an aggregate of distance information to respective points on the object H if reflection light from the object H is imaged on the pickup area 1B. If carriers generated at a deep portion in the semiconductor in response to incidence of near-infrared light for projection are led in a potential well provided in the vicinity of the carrier-generated position opposed to the light incident surface side, high-speed and accurate distance measurement is enabled.

Abstract: In a range image sensor 8, when a first reverse bias voltage applied between a semiconductor substrate 11 and first semiconductor regions 13 is an H bias, first depleted layers A1 and A1 expanding from the p-n junctions of the first semiconductor regions 13 adjacent to each other expand and link to each other so as to cover a second depleted layer B1 expanding from the p-n junction of a second semiconductor region 14. Accordingly, carriers C generated near the rear surface 11a of the semiconductor substrate 11 are reliably captured by the first depleted layers A1. Further, when a second reverse bias voltage applied between the semiconductor substrate 11 and the second semiconductor regions 14 is an H bias, the second depleted layers adjacent to each other expand and link to each other so as to cover the first depleted layer. Accordingly, carriers generated near the rear surface of the semiconductor substrate are reliably captured by the second depleted layers.

Abstract: A pair of first gate electrodes IGR, IGL are provided on a semiconductor substrate 100 so that potentials ?TX1, ?TX2 between a light-sensitive area SA and a pair of first accumulation regions AR, AL alternately ramp. A pair of second gate electrodes IGR, IGL are provided on the semiconductor substrate 100 so as to control the height of first potential barriers ?BG each interposed between the first accumulation region AR, AL and a second accumulation region FDR, FDL, and increase the height of the first potential barrier ?BG to carriers as a higher output of a background light is detected by a photodetector.

Abstract: Two charge quantities (Q1,Q2) are output from respective pixels P (m,n) of the back-illuminated distance measuring sensor 1 as signals d?(m,n) having the distance information. Since the respective pixels P (m,n) output signals d?(m,n) responsive to the distance to an object H as micro distance measuring sensors, a distance image of the object can be obtained as an aggregate of distance information to respective points on the object H if reflection light from the object H is imaged on the pickup area 1B. If carriers generated at a deep portion in the semiconductor in response to incidence of near-infrared light for projection are led in a potential well provided in the vicinity of the carrier-generated position opposed to the light incident surface side, high-speed and accurate distance measurement is enabled.

Abstract: In a range image sensor 8, when a first reverse bias voltage applied between a semiconductor substrate 11 and first semiconductor regions 13 is an H bias, first depleted layers A1 and A1 expanding from the p-n junctions of the first semiconductor regions 13 adjacent to each other expand and link to each other so as to cover a second depleted layer B1 expanding from the p-n junction of a second semiconductor region 14. Accordingly, carriers C generated near the rear surface 11a of the semiconductor substrate 11 are reliably captured by the first depleted layers A1. Further, when a second reverse bias voltage applied between the semiconductor substrate 11 and the second semiconductor regions 14 is an H bias, the second depleted layers adjacent to each other expand and link to each other so as to cover the first depleted layer. Accordingly, carriers generated near the rear surface of the semiconductor substrate are reliably captured by the second depleted layers.