Focal Plane Shift Measurement and Adjustment in a Lens Assembly

What is claimed is: 1 . An integrated sensor and lens assembly, comprising: an image sensor; a lens mount coupled to the image sensor; a lens barrel secured by the lens mount, the lens barrel comprising one or more lenses along an optical axis substantially perpendicular to a focal plane; and one or more strain gauges, a strain gauge of the one or more strain gauges coupled between a lens and the image sensor and structured to measure a shift in a direction along the optical axis between the lens and the image sensor. 2 . The integrated sensor and lens assembly of claim 1 , wherein a second strain gauge of the one or more strain gauges is coupled between a first lens and a second lens of the one or more lenses and structured to measure a second shift in a direction along the optical axis between the first lens and second lens. 3 . The integrated sensor and lens assembly of claim 1 , wherein an electrical resistance of the strain gauge changes responsive to the shift and the electrical resistance change is converted to the shift in a direction along the optical axis between the lens and the image sensor. 4 . The integrated sensor and lens assembly of claim 1 , wherein the shift in the direction along the optical axis between the lens and the image sensor is used to determine a shift in a direction along the optical axis between the focal plane and an image plane. 5 . An integrated image sensor and lens assembly comprising: an image sensor substrate comprising an image sensor in an image plane; a lens mount comprising a tube portion extending in a direction of an optical axis substantially perpendicular to the image plane, the tube portion having a channel; a lens barrel having a first portion extending into the channel of the tube portion, and a second portion outside the channel of the tube portion, the second portion having a camera lens window; and one or more strain gauges, a strain gauge of one or more strain gauges is coupled between the lens window and the image sensor and structured to measure a shift in a direction along the optical axis between the lens window and the image sensor. 6 . The integrated image sensor and lens assembly of claim 5 , wherein the lens barrel comprises one or more lenses and wherein a second strain gauge of the one or more strain gauges is coupled between a first lens and a second lens of the one or more of lenses and configured to measure a second shift in a direction along the optical axis between the first lens and the second lens. 7 . The integrated image sensor and lens assembly of claim 5 , wherein the lens barrel comprises one or more lenses and a second strain gauge of the one or more strain gauges is coupled between a lens and the lens window and configured to measure a second shift in a direction along the optical axis between the lens window and the lens. 8 . The integrated image sensor and lens assembly of claim 5 , wherein the lens barrel comprises one or more lenses and a second strain gauge of the one or more strain gauges is coupled between a lens and the image sensor and configured to measure a second shift in a direction along the optical axis between the lens and the image sensor. 9 . The integrated sensor and lens assembly of claim 5 , wherein an electrical resistance of the strain gauge changes responsive to the shift and the electrical resistance change is converted to the shift in a direction along the optical axis between the lens window and the image sensor. 10 . The integrated sensor and lens assembly of claim 5 , wherein the shift in the direction along the optical axis between the lens window and the image sensor is used to determine a shift in a direction along the optical axis between the focal plane and an image plane. 11 . A camera comprising: one or more strain gauges; an integrated image sensor and lens assembly comprising: an image sensor substrate comprising an image sensor in an image plane; a lens mount comprising a tube portion extending in a direction of an optical axis substantially perpendicular to the image plane, the tube portion having a channel; and a lens barrel having a first portion extending into the channel of the tube portion, and a second portion outside the channel of the tube portion, the second portion having a camera lens window; wherein a strain gauge of the one or more strain gauges is coupled between the lens window and the image sensor and structured to measure a shift in a direction along the optical axis between the lens window and the image sensor. 12 . The camera of claim 11 , wherein the lens barrel comprises one or more lenses and wherein a second strain gauge of the one or more strain gauges is coupled between a first lens and a second lens of the one or more of lenses and configured to measure a second shift in a direction along the optical axis between the first lens and the second lens. 13 . The camera of claim 11 , wherein the lens barrel comprises one or more lenses and a second strain gauge of the one or more strain gauges is coupled between a lens and the lens window and configured to measure a second shift in a direction along the optical axis between the lens window and the lens. 14 . The camera of claim 11 , wherein the lens barrel comprises one or more lenses and a second strain gauge of the one or more strain gauges is coupled between a lens and the image sensor and configured to measure a second shift in a direction along the optical axis between the lens and the image sensor. 15 . The camera of claim 11 , further comprises a shift measurement module configured to measure an electrical resistance change of the strain gauge responsive to the shift and to convert the measured electrical resistance change to the shift in a direction along the optical axis between the lens window and the image sensor. 16 . The camera of claim 15 , further comprises a shift determination module configured to determine a shift between the image plane and the focal plane based on the shift in the direction along the optical axis between the lens window and the image sensor. 17 . The camera of claim 16 , further comprises a shift compensation module configured to correct for an optical aberration resulting from the shift between the lens window and the image sensor. 18 . A method, comprising: measuring an electrical resistance change of a strain gauge coupled between a lens and an image sensor of a camera; converting the measured electrical resistance to a shift between the lens and the image sensor of the camera; determining a shift between an image plane and a focal plane of the camera based on the shift between the lens and the image sensor of the camera; and correcting for optical aberration resulting from the determined shift between the image plane and the focal plane of the camera. 19 . The method of claim 18 , wherein the step of determining the shift comprises looking up the shift between the lens and the image sensor of the camera in a table to determine the shift between the image plane and the focal plane of the camera. 20 . The method of claim 18 , wherein the correcting for optical aberration comprises determining the optical aberration based on the determined shift and applying one or more image processing techniques to substantially minimize the determined optical aberration.