Paul A Bohn, 42103 Cambridge Cir, Madison, AL 35758

2020000, Jan 2, 2020

Jun 27, 2019

16/455001

- Cambridge MA, US
Paul Aaron Bohn - Huntsville AL, US
Juha-Pekka Laine - Boston MA, US
Francis J. Rogomentich - Wilmington MA, US

G02B 23/02
G02B 17/08
G02B 5/08
H04N 5/225

An optical system such as an imaging system, projecting system or combined imaging and projecting system, has complex dielectric coatings and/or reflecting polarizers to separate multiple spectral bands and/or polarizations on one or more of the system's curved mirrors.

2020000, Jan 2, 2020

Jun 27, 2019

16/454998

- Cambridge MA, US
Adam Kelsey - Cambridge MA, US
Paul Aaron Bohn - Huntsville AL, US
Stephanie L. Golmon - Arlington MA, US
Francis J. Rogomentich - Wilmington MA, US
Juha-Pekka Laine - Boston MA, US
Buddy A. Clemmer - Burlington MA, US
David A. Landis - Palm Harbor FL, US

G06K 9/62
G01S 13/86
G01S 17/88

A potentially small, gimballed, multi-sensor system employs a shared aperture for at least some of the image sensors. Applications include intelligence, surveillance, target acquisition and reconnaissance (ISTAR), and guiding autonomous vehicles. The system can actively blend images from multiple spectral bands for clarity and interpretability, provide remote identification of objects and material, provide anomaly detection, control lasers and opto-mechanics for image quality, and use shared aperture using folded optics.

2018031, Nov 1, 2018

Jun 27, 2018

16/020563

- Cambridge MA, US
Gregory P. Blasche - Burlington MA, US
Matthew T. Jamula - Wilmington MA, US
Paul A. Bohn - St. Petersburg FL, US
Robin Mark Adrian Dawson - Waltham MA, US
Benjamin F. Lane - Sherborn MA, US
Eric T. Hoke - Somerville MA, US
Daniel M. Meiser - Providence RI, US
Joseph M. Kinast - Arlington MA, US
Stephen P. Smith - Acton MA, US

G01C 21/00
G01S 19/45
G01C 21/02
G01C 21/04
G01C 21/16
G06K 9/00

Methods and apparatus automatically determine a location, such as of an aircraft or spacecraft, by matching images of terrain below the craft, as captured by a camera, radar, etc. in the craft, with known or predicted terrain landmark data stored in an electronic data store. A star tracker measures attitude of the camera. An additional navigation aiding sensor provides additional navigational data. Optionally, a rangefinder measures altitude of the camera above the terrain. A navigation filter uses the attitude, the additional navigational data, and optionally the altitude, to resolve attitude, and optionally altitude, ambiguities and thereby avoid location solution errors common in prior art terrain matching navigation systems.

2018022, Aug 9, 2018

Feb 5, 2018

15/888306

- Cambridge MA, US
Matthew A. Sinclair - Stoneham MA, US
Juha-Pekka J. Laine - Boston MA, US
Paul A. Bohn - St. Petersburg FL, US
Robin Dawson - Waltham MA, US

G02B 27/00
G02B 1/04
G02B 6/06
G02B 27/64
H04N 5/225

An optical device is described for a wide field of view optical system. A device housing has an optical opening into an enclosed interior volume. A multi-element lens is molded across the optical opening and defined by: a. a field of view representing a volume of space from which light is collected, b. a plurality of optical paths through the lens defining one or more focal planes within the interior volume, and c. a boresight axis perpendicular to each of the one or more focal planes. Optical sensors are arranged on the one or more focal planes and configured for sensing light collected through the lens from the field of view. The device forms a single environmentally hardened package configured to absorb impulse shocks without disturbing the boresight axis or the plurality of optical paths.

2018012, May 3, 2018

Nov 3, 2017

15/803367

- Cambridge MA, US
Simone B. Bortolami - Belmont MA, US
Jeffrey Korn - Lexington MA, US
Gregory P. Blasche - Burlington MA, US
Matthew T. Jamula - Wilmington MA, US
Paul A. Bohn - St. Petersburg FL, US
Robin Mark Adrian Dawson - Waltham MA, US
Benjamin F. Lane - Sherborn MA, US
Eric T. Hoke - Somerville MA, US
Daniel M. Meiser - Providence RI, US
Joseph M. Kinast - Cambridge MA, US
Timothy J. McCarthy - Danvers MA, US
Stephen P. Smith - Acton MA, US

G01C 21/36
G06T 7/73
H04W 4/02

A visual navigation system includes a compass configured to orient a user in a heading direction, an image sensor configured to capture a series of successive navigation images in the heading direction, one or more of the navigation images having at least two reference markers, data storage memory configured to store the series of successive navigation images, a navigation processor configured to identify at least one principal marker and at least one ancillary marker from the at least two reference markers, the principal marker positioned within a principal angle and the ancillary marker positioned within an ancillary angle, which is greater than the principal angle, and to determine heading direction information based on a position of the at least one principal marker and/or the at least one ancillary marker in the successive navigation images, and a user interface configured to provide the heading direction information to the user.

2018008, Mar 22, 2018

Sep 16, 2016

15/267918

- Cambridge MA, US
Gregory P. Blasche - Burlington MA, US
Matthew T. Jamula - Brighton MA, US
Paul A. Bohn - St. Petersburg FL, US
Robin Mark Adrian Dawson - Waltham MA, US
Benjamin F. Lane - Sherborn MA, US
Eric T. Hoke - Somerville MA, US
Daniel M. Meiser - Providence RI, US
Joseph M. Kinast - Cambridge MA, US
Stephen P. Smith - Acton MA, US

G01C 21/36
G01C 21/00
G06K 9/00
G01C 21/02
G01C 21/30

Methods and apparatus automatically determine a location, such as of an aircraft or spacecraft, by matching images of terrain below the craft, as captured by a camera, radar, etc. in the craft, with known or predicted terrain landmark data stored in an electronic data store. A star tracker measures attitude of the camera. Optionally, a rangefinder measures altitude of the camera above the terrain. A navigation filter uses the attitude, and optionally the altitude, to resolve attitude, and optionally altitude, ambiguities and thereby avoid location solution errors common in prior art terrain matching navigation systems.

2016038, Dec 29, 2016

Jun 23, 2015

14/746970

- Cambridge MA, US
Gregory P. Blasche - Burlington MA, US
Paul Bohn - Brighton MA, US
Robin Mark Adrian Dawson - Waltham MA, US
Walter Foley - Colton NY, US
Samuel Harrison - Acton MA, US
Matthew T. Jamula - Brighton MA, US
Juha-Pekka J. Laine - Boston MA, US
Benjamin F. Lane - Grafton MA, US
Sean McClain - Somerville MA, US
Francis J. Rogomentich - Wilmington MA, US
Stephen P. Smith - Acton MA, US
John James Boyle - Bourne MA, US

H04N 5/225
G02B 13/00
H04N 5/232

A digital camera optically couples a monocentric lens to image sensor arrays, without optical fibers, yet shields the image sensor arrays from stray light. In some digital cameras, baffles are disposed between an outer surface of a monocentric lens and each image sensor array to shield the image sensor arrays from stray light. In other such digital cameras, an opaque mask defines a set of apertures, one aperture per image sensor array, to limit the amount of stray light. Some digital cameras include both masks and baffles.

2016037, Dec 22, 2016

Jun 17, 2016

15/186051

- Cambridge MA, US
- Roanoke VA, US
Marc McConley - Andover MA, US
Gregory Blasche - Burlington MA, US
Paul Bohn - St. Petersburg FL, US
Matthew S. Bottkol - Boston MA, US
Michael Ricard - Natick MA, US
Evan M. Lally - Blacksburg VA, US
Sandra M. Klute - Blacksburg VA, US
Matthew T. Reaves - Baltimore MD, US
Emily H. Templeton - Blacksburg VA, US
James Donna - Watertown MA, US

G01B 11/16
G01D 5/26
G01C 19/00

Systems and methods for determining the shape and/or position of an object are described. A fiber optic shape sensor (FOSS) may be used in combination with one or more inertial measurement units (IMUs) to mutually cross-correct for errors in the sensors' measurements of position and/or orientation. The IMU(s) may be attached to the FOSS's optical fiber, such that each IMU measures the orientation of a corresponding portion of the optical fiber. The position and shape of the optical fiber can then be determined based on the measurements obtained from the IMU(s) and the measurements obtained from the FOSS. For example, the FOSS measurements and the IMU measurements can be provided to a state estimation unit (e.g., a Kalman filter), which can estimate the position and/or shape of the optical fiber based on those measurements. In some embodiments, the estimates of position are used for navigation of tethered mobile devices.