Optics systems presented are arranged as high-performance imagers particularly characterized by their exceptional compactness in view of image quality. A plurality of lens and let's and or doublets are configured to cooperate with related mount systems optimized for compactness. To achieve very high resolution imaging despite somewhat abbreviated compound lens design, these systems include use of lens array elements proximate to an imaging plane. So placed lens array devices may be designed with lens elements which invariably operate on incident wave planes with radial dependence. That is, the focusing strength of lenses from which these lens arrays are comprised may depend upon its distance from system optic axis. This enables an imaging correction function that counters distortion and other undesirable imaging errors typically present in a simplified compound lens systems. When used together and in conjunction with special-purpose collapsing lens mounting systems, an imaging system of very high fidelity and very compact weight size is achieved to great advantage in system when a premium on lens size is necessitated.

A customizable attachable food holding device includes a main body having an upper body section that is hingedly secured to a lower body section, so as to transition between a generally flat orientation and a folded orientation. The main body is constructed from a paper product, and the lower body section includes a pair of folding side sections which fold beneath the upper body section. An adhesive is positioned along one surface of the lower body section, and a food receptacle is secured onto the upper body section via a connector.

The disclosure includes a monopod adapted for a pack or harness. It utilizes a simple mechanism which is lightweight, self-contained and easy to set-up and take down. The user never has to access another piece of equipment, nor assemble or disassemble any parts in use. Indeed, the user can access or store binoculars while on the move. The user can also shift to other fields of view instantly, without having to turn, re-level or adjust the set-up, as would be required with a tripod. The disclosure comprises a scope bracket configured to rotatably attach to a scope mount. A telescoping arm attaches to the scope bracket in a first angle relative to the telescoping arm. A telescoping arm bracket rotatably attaches to the telescoping arm in a second angle relative to the telescoping arm. A back plate supports the telescoping arm bracket against a chest of a user.

The disclosure includes a monopod adapted for a pack or harness. It utilizes a simple mechanism which is lightweight, self-contained and easy to set-up and take down. The user never has to access another piece of equipment, nor assemble or disassemble any parts in use. Indeed, the user can access or store binoculars while on the move. The user can also shift to other fields of view instantly, without having to turn, re-level or adjust the set-up, as would be required with a tripod. The disclosure comprises a scope bracket configured to rotatably attach to a scope mount. A telescoping arm attaches to the scope bracket in a first angle relative to the telescoping arm. A telescoping arm bracket rotatably attaches to the telescoping arm in a second angle relative to the telescoping arm. A back plate supports the telescoping arm bracket against a chest of a user.

The invention of the current application is directed to a 3-dimensional viewing device with stereoscopic affect including a main linear body including at least one inner lining layer, and a mirror assembly. The at least one inner lining is positioned within the main linear body and the mirror assembly is positioned inside the main linear body where the perimeter of the mirror assembly is surrounded by the at least one inner lining. The mirror assembly includes at least two mirrors. The 3-dimensional viewing device with stereoscopic affect also includes an image holder assembly including a gear assembly, and an endcap including a viewing hole. The endcap is attached to a first end of the main linear body and the second end of the main linear body at least partially inserts into an opening in the image holder assembly.

A large reflector inflatable telescope. The telescope has an inflatable hull with a conical lower portion and a hemispherical upper portion. The conical portion is transparent to electromagnetic waves so that radio or light waves can reach an inner reflector, which is interposed between the conical portion and the hemispherical portion. The presence of the inner reflector allows the conical portion and the hemispherical portion to be inflated at different pressures such that the reflector becomes spherical or parabolic. If desired, the reflector can be made adjustable with a membrane behind the reflector that provides electro-static force to shape the reflector.

A mobile self-unloading observatory is presented for transporting observation equipment such as a telescope to a remote location, with a subsequent automatic setting up the equipment for observation. The observation equipment is transported on a suspended platform that protects the equipment against shock and vibrations. At the remote location, a self-leveling telescopic pier is extended to the ground under the chassis of the observatory, and released from being held within a frame of the observatory. The telescopic pier is extended towards the platform to support the observation equipment over the ground. The transportation, the setting up, and the teardown of the equipment may be performed without having to manually handle heavy or bulky objects.

A mobile self-unloading observatory is presented for transporting observation equipment such as a telescope to a remote location, with a subsequent automatic setting up the equipment for observation. The observation equipment is transported on a suspended platform that protects the equipment against shock and vibrations. At the remote location, a self-leveling telescopic pier is extended to the ground under the chassis of the observatory, and released from being held within a frame of the observatory. The telescopic pier is extended towards the platform to support the observation equipment over the ground. The transportation, the setting up, and the teardown of the equipment may be performed without having to manually handle heavy or bulky objects.

The disclosure includes a monopod adapted for a pack or harness. It utilizes a simple mechanism which is lightweight, self-contained and easy to set-up and take down. The user never has to access another piece of equipment, nor assemble or disassemble any parts in use. Indeed, the user can access or store binoculars while on the move. The user can also shift to other fields of view instantly, without having to turn, re-level or adjust the set-up, as would be required with a tripod. The disclosure comprises a scope bracket configured to rotatably attach to a scope mount. A telescoping arm attaches to the scope bracket in a first angle relative to the telescoping arm. A telescoping arm bracket rotatably attaches to the telescoping arm in a second angle relative to the telescoping arm. A back plate supports the telescoping arm bracket against a chest of a user.

The disclosure includes a monopod adapted for a pack or harness. It utilizes a simple mechanism which is lightweight, self-contained and easy to set-up and take down. The user never has to access another piece of equipment, nor assemble or disassemble any parts in use. Indeed, the user can access or store binoculars while on the move. The user can also shift to other fields of view instantly, without having to turn, re-level or adjust the set-up, as would be required with a tripod. The disclosure comprises a scope bracket configured to rotatably attach to a scope mount. A telescoping arm attaches to the scope bracket in a first angle relative to the telescoping arm. A telescoping arm bracket rotatably attaches to the telescoping arm in a second angle relative to the telescoping arm. A back plate supports the telescoping arm bracket against a chest of a user.