Company Filing History:
Years Active: 2005
Title: William D Haskell: Innovator in Photographic Scaling Technology
Introduction
William D Haskell is an accomplished inventor based in Mims, Florida. He is known for his innovative contributions to photographic technology, particularly in the development of devices that enhance the accuracy of image scaling. His work has significant implications for various fields, including photography and remote object analysis.
Latest Patents
Haskell holds a patent for a "Scaling device for photographic images." This device projects a known optical pattern into the field of view of a camera, serving as a reference scale for photographs of remote objects. The scaling device comprises an optical beam projector that emits two or more spaced, parallel optical beams onto the surface of an object to be photographed. The resulting beam spots or lines are spaced apart by a predetermined distance, allowing for accurate size comparisons of other objects in the photograph. The device is designed to be small and battery-powered, making it easy to attach to a camera. It utilizes one or more laser light sources and associated optics to generate the parallel light beams.
Career Highlights
Haskell's career is marked by his association with the United States of America as represented by the Administrator of NASA. His work in this capacity has allowed him to contribute to advancements in technology that support scientific research and exploration. His innovative scaling device exemplifies his commitment to enhancing photographic techniques and improving measurement accuracy in various applications.
Collaborations
Haskell has collaborated with notable coworkers, including Jorge E Rivera and Robert C Youngquist. These partnerships have fostered a collaborative environment that encourages innovation and the sharing of ideas.
Conclusion
William D Haskell's contributions to photographic technology through his scaling device patent demonstrate his ingenuity and dedication to advancing the field. His work continues to influence how we capture and analyze images of remote objects.