Abstract: Provided are a solid-state imaging device, a method for driving a solid-state imaging device, and an electronic apparatus capable of reading signals produced with different conversion gains and having different signal directions. A pixel signal processing part 400 includes a first reading part 410 and a second reading part 420. Of a pixel signal PIXOUT input into an input node ND401, the first reading part 410 inverts the signal direction of a first-conversion-gain signal (HCGRST, HCGSIG) and outputs an inverted first-conversion-gain signal (HCGRST, HCGSIG), which has been subjected to inversion and amplification, to an AD converting part 430 via a connection node ND402. Of the pixel signal PIXOUT input into the input node ND401, the second reading part 420 keeps the signal direction of a second-conversion-gain signal (LCGSIG, LCGRST) unchanged, and outputs a non-inverted second-conversion-gain signal (LCGSIG, LCGRST) to the AD converting part 430 via the connection node ND402.

Abstract: A solid-state imaging device, a method for driving a solid-state imaging device and an electronic apparatus are capable of reducing kTC noise of a LCG signal, preventing a drop in SNR at the conjunction point between a HCG signal and the LCG signal, and eventually achieving improved image quality. At a start of a reset period, first and second reset transistors are switched into a conduction state. During a predetermined first period after the reset period starts, the first reset line is kept connected to a reset potential. After the first period elapses, the second reset transistor is switched into a non-conduction state to switch the first reset line into a floating state, so that the first reset line has high impedance. After a second period elapses and when the reset period ends, the first reset transistor is switched into the non-conduction state.

Abstract: A solid-state imaging device, a method for driving the same, and an electronic apparatus can achieve a high dynamic range based on multiple exposure technique, where images captured with different exposure durations are combined, with it being possible to prevent motion artifacts and LED flickers. A pixel has a 4:0 configuration. The pixel is divided into, for example, four sub-pixels all of which have the same color (for example, G (green)). An access control part sets different charge integration periods and different charge storage starting times between photoelectric conversion parts PD of the sub-pixels and controls the charge integration periods such that they overlap each other. In other words, the access control part sets different charge integration periods and different charge storage starting times, the number of which corresponds to the number of sub-pixels having the same color, and controls the charge integration periods such that they overlap each other.

Abstract: Provided are a solid-state imaging device, a method for driving a solid-state imaging device, and an electronic apparatus capable of reading signals produced with different conversion gains and having different signal directions. A pixel signal processing part 400 includes a first reading part 410 and a second reading part 420. Of a pixel signal PIXOUT input into an input node ND401, the first reading part 410 inverts the signal direction of a first-conversion-gain signal (HCGRST, HCGSIG) and outputs an inverted first-conversion-gain signal (HCGRST, HCGSIG), which has been subjected to inversion and amplification, to an AD converting part 430 via a connection node ND402. Of the pixel signal PIXOUT input into the input node ND401, the second reading part 420 keeps the signal direction of a second-conversion-gain signal (LCGSIG, LCGRST) unchanged, and outputs a non-inverted second-conversion-gain signal (LCGSIG, LCGRST) to the AD converting part 430 via the connection node ND402.

Abstract: A solid-state imaging device, a method for driving the same, and an electronic apparatus can achieve a high dynamic range based on multiple exposure technique, where images captured with different exposure durations are combined, with it being possible to prevent motion artifacts and LED flickers. A pixel has a 4:0 configuration. The pixel is divided into, for example, four sub-pixels all of which have the same color (for example, G (green)). An access control part sets different charge integration periods and different charge storage starting times between photoelectric conversion parts PD of the sub-pixels and controls the charge integration periods such that they overlap each other. In other words, the access control part sets different charge integration periods and different charge storage starting times, the number of which corresponds to the number of sub-pixels having the same color, and controls the charge integration periods such that they overlap each other.

Abstract: The present technology relates to a light receiving device and a distance measuring module capable of curbing a decrease in distance measurement accuracy due to an increase in the number of pixels. A light receiving device includes a pixel array unit in which pixels each having a first tap detecting charge photoelectrically converted by a photoelectric conversion unit and a second tap detecting charge photoelectrically converted by the photoelectric conversion unit are two-dimensionally arranged in a matrix. In the pixel array unit, four vertical signal lines for outputting a detection signal detected by any one of the first tap and the second tap to the outside of the pixel array unit are arranged for one pixel column. The present technology can be applied to a distance measuring sensor or the like of the indirect ToF scheme, for example.

Abstract: The present technology relates to a light receiving device and a distance measuring module capable of improving sensitivity. A light receiving device includes a pixel array unit in which pixels each having a first tap detecting charge photoelectrically converted by a photoelectric conversion unit and a second tap detecting charge photoelectrically converted by the photoelectric conversion unit are two-dimensionally arranged in a matrix. The first tap and the second tap each have a voltage application unit that applies a voltage, the pixel array unit has a groove portion formed by digging from a light incident surface side of a substrate to a predetermined depth, and the groove portion is arranged so as to overlap at least a part of the voltage application unit in plan view. The present technology can be applied to a distance measuring sensor or the like of the indirect ToF scheme, for example.

Abstract: A charge-modulation element includes a first charge-accumulation region, a second charge-accumulation region, a third charge-accumulation region, and a fourth charge-accumulation region, provided symmetric with respect to a center position of a light-receiving area, and a first field-control electrode pair, a second field-control electrode pair, a third field-control electrode pair, and a fourth field-control electrode pair, arranged on both sides of respective charge transport paths, for changing depletion potentials of the charge transport paths, which extend from the center position of the light-receiving area to the first charge-accumulation region, the second charge-accumulation region, the third charge-accumulation region, and the fourth charge-accumulation region.

Abstract: A charge-modulation element includes a first charge-accumulation region, a second charge-accumulation region, a third charge-accumulation region, and a fourth charge-accumulation region, provided symmetric with respect to a center position of a light-receiving area, and a first field-control electrode pair, a second field-control electrode pair, a third field-control electrode pair, and a fourth field-control electrode pair, arranged on both sides of respective charge transport paths, for changing depletion potentials of the charge transport paths, which extend from the center position of the light-receiving area to the first charge-accumulation region, the second charge-accumulation region, the third charge-accumulation region, and the fourth charge-accumulation region.

Abstract: Airborne dust is controlled and minimized by spraying a fine spray mist by nozzles (50) in a direction tangential to and spaced from spaced, vertical, parallel axes of counter-rotating first and second front brooms (26) and opposite to the rotation direction and angled to the floor in front of the axes. The fluid is pumped at a rate in the order of 0.033 gallons (125 ml) per minute and at a pressure in the order of 40 psi (2.81 kg/cm) through the nozzles (50) having orifice diameters in the order of 0.015 inch (0.38 cm) and a spray angle in the order of 110° to produce droplets having a volume mean diameter in the order of less than 220 microns. The fine spray mist adheres to the airborne particulates to control settling of the airborne particles onto the floor and without build-up of moisture on the floor being swept.