An apparatus comprising means for: causing illumination of different areas of a sample with an optical frequency imaging beam at different positions at different times, wherein adjacent positions are configured to cause the corresponding areas to at least partially overlap; receiving signals indicative of back-scattering of the optical frequency imaging beam from the sample at the different times; and processing the received signals to obtain an image of the sample, wherein processing the received signals compensates for phase variations between the different positions at the different times using a matched filter derived from a scattering model of the sample.

A vehicle wheel alignment rack is described herein that includes at least one laser and a target. The laser is removably coupled to a wheel of a vehicle. The target corresponds to the laser and is disposed at an opposite end of the vehicle from the laser. The target is directly and removably coupled to a frame of the vehicle such that the target is aligned with the frame at a known angle. The wheel is aligned to the frame by comparing the known angle to an expected and actual position on the target where a beam of light from the laser strikes the target. Some embodiments of the claimed invention include at least a second laser and a second target similarly disposed. Various means of coupling the target or targets to the frame are also disclosed herein.

A vehicle measurement station utilizing one or more displacement sensors disposed on each opposite side of an inspection region of a vehicle inspection lane to acquire displacement measurement data along associated measurement axes. At least a portion of the displacement measurement data is associated with the outermost wheel assemblies on an axle of a moving vehicle passing through the inspection region, and utilized to determine one or more vehicle characteristics, such as an axle total toe condition.

A vehicle measurement station utilizing one or more displacement sensors disposed on each opposite side of an inspection region of a vehicle inspection lane to acquire displacement measurement data along associated measurement axes. At least a portion of the displacement measurement data is associated with the outermost wheel assemblies on an axle of a moving vehicle passing through the inspection region, and utilized to determine one or more vehicle characteristics, such as an axle total toe condition.

An alignment system for aligning the wheels of a vehicle. The alignment system measures caster and camber of the treat wheels of the vehicle. The system includes four alignment heads, each alignment head having a laser, a target, and a transmitter/receiver. A rim clamp communicatively couples each alignment head to the wheel of the vehicle. A turn plates is positioned below each front wheel of the vehicle.

A method for creating a boundless projected interactive virtual desktop, wherein the interactive virtual desktop comprises an adjustable image of a projected portion of an area associated with at least one desktop of a computing device is provided. The method may include integrating a projector and a motion sensor into a device. The method may also include capturing at least one of a location, a change in location, a change in direction, or a change in orientation associated with the device. The method may include computing a projected image. The method may also include coordinating the computed projected image across at least one application running in the device. The method may further include projecting a view of a portion of an area associated with the coordinated projected image, wherein the projected view comprises an interactive virtual desktop. The method may additionally include adjusting the projected view based on a criteria.

A system and process for aligning wheels of a three-wheel cycle include mounting targets to two wheels on an axle of the three-wheel cycle and positioning an alignment device relative to a single wheel of the three-wheel cycle to create a virtual axle and assess thrust angle. Once targets are in place, thrust angle is reduced to zero, and camber, caster, and toe measurements are taken and adjusted as needed to achieve three-wheel alignment.

A vehicle wheel alignment rack is described herein that includes at least one laser and a target. The laser is removably coupled to a wheel of a vehicle. The target corresponds to the laser and is disposed at an opposite end of the vehicle from the laser. The target is directly and removably coupled to a frame of the vehicle such that the target is aligned with the frame at a known angle. The wheel is aligned to the frame by comparing the known angle to an expected and actual position on the target where a beam of light from the laser strikes the target. Some embodiments of the claimed invention include at least a second laser and a second target similarly disposed. Various means of coupling the target or targets to the frame are also disclosed herein.

A method for creating a boundless projected interactive virtual desktop, wherein the interactive virtual desktop comprises an adjustable image of a projected portion of an area associated with at least one desktop of a computing device is provided. The method may include integrating a projector and a motion sensor into a device. The method may also include capturing at least one of a location, a change in location, a change in direction, or a change in orientation associated with the device. The method may include computing a projected image. The method may also include coordinating the computed projected image across at least one application running in the device. The method may further include projecting a view of a portion of an area associated with the coordinated projected image, wherein the projected view comprises an interactive virtual desktop. The method may additionally include adjusting the projected view based on a criteria.

A method for creating a boundless projected interactive virtual desktop, wherein the interactive virtual desktop comprises an adjustable image of a projected portion of an area associated with at least one desktop of a computing device is provided. The method may include integrating a projector and a motion sensor into a device. The method may also include capturing at least one of a location, a change in location, a change in direction, or a change in orientation associated with the device. The method may include computing a projected image. The method may also include coordinating the computed projected image across at least one application running in the device. The method may further include projecting a view of a portion of an area associated with the coordinated projected image, wherein the projected view comprises an interactive virtual desktop. The method may additionally include adjusting the projected view based on a criteria.