Abstract: Described herein is a pinned photodiode pixel architecture having a p-type substrate that is independently biased with respect to a pixel area to provide an avalanche region between an n-type region and a p-type region formed on the substrate. Such a pinned photodiode pixel can be used in imaging sensors that are used in low light level conditions.

Abstract: Described herein is a pixel readout circuit which provides readout at two sensitivity levels depending on the amount of electrons generated by a pixel photodiode in the circuit. A floating diffusion capacitor operates to store charge up to a saturation value determined by its capacitance and an overflow capacitor is provided in an overflow region for storing charge above the saturation value of the floating diffusion capacitor. Readout at a high sensitivity level is provided when the floating diffusion capacitor is not saturated and readout at a lower sensitivity level is provided when there is saturation and subsequent overflow to the overflow region. Connection of the floating diffusion capacitor to the overflow capacitor shares the charge over the combined capacitance of the two capacitors and provides readout at a lower sensitivity without loss of charge.

Abstract: Described herein is a pixel readout circuit which provides readout at two sensitivity levels depending on the amount of electrons generated by a pixel photodiode in the circuit. A floating diffusion capacitor operates to store charge up to a saturation value determined by its capacitance and an overflow capacitor is provided in an overflow region for storing charge above the saturation value of the floating diffusion capacitor. Readout at a high sensitivity level is provided when the floating diffusion capacitor is not saturated and readout at a lower sensitivity level is provided when there is saturation and subsequent overflow to the overflow region. Connection of the floating diffusion capacitor to the overflow capacitor shares the charge over the combined capacitance of the two capacitors and provides readout at a lower sensitivity without loss of charge.

Abstract: Described herein is a pinned photodiode pixel architecture having a p-type substrate that is independently biased with respect to a pixel area to provide an avalanche region between an n-type region and a p-type region formed on the substrate. Such a pinned photodiode pixel can be used in imaging sensors that are used in low light level conditions.

Abstract: Methods of fabricating complementary metal-oxide-semiconductor (CMOS) imagers for backside illumination are disclosed. In one embodiment, the method may include forming at a front side of a substrate a plurality of high aspect ratio trenches having a predetermined trench depth, and forming at the front side of the substrate a plurality of photodiodes, where each photodiode is adjacent at least one trench. The method may further include forming an oxide layer on inner walls of each trench, removing the oxide layer, filling each trench with a highly doped material, and thinning the substrate from a back side opposite the front side to a predetermined final substrate thickness. In some embodiments, the substrate may have a predetermined doping profile, such as a graded doping profile, that provides a built-in electric field suitable to guide the flow of photogenerated minority carriers towards the front side.

Abstract: The present invention is related to a method for aligning and bonding a first element (1) and a second element (2), comprising: obtaining a first element (1) having at least one protrusion, the protrusion having a base portion (12) made of a first material and an upper portion (13) made of a second, deformable material, different from the first material; obtaining a second element (2) having a first main surface and second main surface (8) and at least one through-hole between the first and second main surface; placing the first and second element onto each other; receiving in the through-hole of the second element (2) the protrusion of the first element (1), the protrusion being arranged and constructed so as to extend from an opening of the through-hole in the first main surface to a position beyond an opening of the through-hole in the second main surface (8); deforming the deformable portion (13) of the protrusion, such that the deformed portion mechanically fixes the second element (2) on the first el

Abstract: Methods of fabricating complementary metal-oxide-semiconductor (CMOS) imagers for backside illumination are disclosed. In one embodiment, the method may include forming at a front side of a substrate a plurality of high aspect ratio trenches having a predetermined trench depth, and forming at the front side of the substrate a plurality of photodiodes, where each photodiode is adjacent at least one trench. The method may further include forming an oxide layer on inner walls of each trench, removing the oxide layer, filling each trench with a highly doped material, and thinning the substrate from a back side opposite the front side to a predetermined final substrate thickness. In some embodiments, the substrate may have a predetermined doping profile, such as a graded doping profile, that provides a built-in electric field suitable to guide the flow of photogenerated minority carriers towards the front side.