Abstract: A television antenna formed from a pair of generally sinuous antenna arms extending outwardly from a common central axis and arranged opposite each other. The antenna arms do not interleave or touch each other. A reflector provides a separation distance between the reflector and the pair of antenna arms.

Abstract: A television antenna formed from a pair of generally sinuous antenna arms extending outwardly from a common central axis and arranged opposite each other. The antenna arms do not interleave or touch each other. A reflector provides a separation distance between the reflector and the pair of antenna arms.

Abstract: A stabilizer platform mounted to a vessel for positioning a satellite dish antenna in the azimuth and elevation directions. An azimuth motor and an elevation motor are mounted in a formed hollow interior of a housing. Azimuth motor control cables and elevation motor control cables are connected to the motors to carry signals and power for controlling the operation of the motors. On top of housing is mounted a platform which rotates in the azimuth direction with respect to the housing. The azimuth motor is coupled to the platform through a gear arrangement and rotates the platform. On top of the platform is mounted an elevation drive which holds the satellite dish antenna. Mounted in the platform is an elevation gear cluster which rotates with respect to the platform. The elevation gear cluster is coupled to the elevation drive. The elevation motor drives the elevation gear cluster so that the elevation motor can move the satellite dish antenna in the elevation direction.

Abstract: A retractable antenna clamp that allows for easy and quick adjustment of an antenna, especially an antenna attached to an RV, boat or camper. The retractable antenna clamp comprises a tension device which holds the antenna shaft in place within a mounting bracket that is attached to a support surface of an RV, camper, boat, or the like. Antenna adjustment is accomplished by releasing the grip of the tension device on the antenna shaft so that the antenna may be raised, lowered or rotated as needed.

Abstract: A stabilizer platform mounted to a vessel for positioning a satellite dish antenna in the azimuth and elevation directions. An azimuth motor and an elevation motor are mounted in a formed hollow interior of a housing. Azimuth motor control cables and elevation motor control cables are connected to the motors to carry signals and power for controlling the operation of the motors. On top of housing is mounted a platform which rotates in the azimuth direction with respect to the housing. The azimuth motor is coupled to the platform through a gear arrangement and rotates the platform. On top of the platform is mounted an elevation drive which holds the satellite dish antenna. Mounted in the platform is an elevation gear cluster which rotates with respect to the platform. The elevation gear cluster is coupled to the elevation drive. The elevation motor drives the elevation gear cluster so that the elevation motor can move the satellite dish antenna in the elevation direction.

Abstract: A satellite dish antenna targeting device which corrects for incline and parabolic offset angle. The satellite dish antenna is connected to a base by a support member so that the satellite dish antenna is able to move through an elevation. An inclinometer is mounted to move in unison with the satellite dish antenna for sensing when the base is oriented at an inclination angle with respect to a tangent to the earth at a location where the satellite dish antenna is being targeted. The inclinometer further senses the elevation the satellite dish antenna moves through. The inclinometer thereby provides a dish elevation corrected for the incline and elevation of the satellite dish antenna to a microprocessor. The microprocessor corrects the dish elevation for the parabolic offset angle of the satellite dish antenna. A display device connected to the microprocessor displays a corrected dish elevation of the satellite dish antenna.

Abstract: A portable satellite dish antenna system for carrying by a user to a remote location. The system includes a base mount having a peripheral edge with a handle formed thereon. A length of cable is stowed in a carrier in the mount. A pivoting mechanism is connected to the dish and to the mount to move the dish between a carrying position and a deployed position. In the carrying position, the dish is held parallel to the mount and the handle. The mount has a formed opening opposite the handle. This enables the feed horn, when in the carrying position, to locate in the formed opening, thereby reducing the space between the dish and the mount during carrying. The user of the system grips the handle and twists the mount in a direction to align the dish with a desired direction based on a compass reading located on the mount. The mount has a formed linear track located between the handle and the formed opening having a plurality of elevation marks.

Abstract: A TVRO satellite dish antenna system mounted on the roof of a parked vehicle automatically determines its location and bearing relative to two geosynchronous satellites and then uses this information to accurately calculate the azimuths and elevations of any other geosynchronous satellites. A magnetic compass generates a magnetic bearing signal for the system. An estimated latitude and longitude for the vehicle are provide by the user based on the approximate geographic location of the vehicle. The estimated positions for a first geosynchronous satellite and a second geosynchronous satellite relative to the satellite dish antenna are calculated from this information. The satellite dish antenna is moved to an initial search position corresponding to the estimated position of the first satellite and then moved in a search pattern until the receiver detects a signal peak for a selected channel.

Abstract: A deployable satellite antenna system is intended primarily to be mounted to the roof of a vehicle, such as a recreational vehicle. The elevational position of the reflector is controlled by a reflector support having a lower portion pivotably attached to a base mounted to the vehicle. The elevational position of the reflector can be adjusted between a stowed position in which the reflector is stored face-up adjacent to the vehicle and a deployed position. The feed horn is supported at the distal end of a feed arm having a first segment attached to the reflector support extending outward between the base and reflector, and a second segment pivotably connected to the distal end of the first segment. The feed horn segments move between an extended position in which the feed horn is positioned to receive signals reflected from the reflector, and a folded position in which the feed horn is positioned adjacent to the reflector.

Abstract: A system is described for vertically stacking a plurality of satellite dishes for bulk transport and storage using minimal space. Each satellite dish has a parabolic dish with a stacking rim attached to its outer periphery at an angle of about 125 degrees. The stacking rim has two circumferential support regions on opposite surfaces. When the satellite dishes are stacked vertically, the support regions of the stacking rims abut, leaving a space between the parabolic surfaces of adjacent dishes. This space has the same dimensions as the thickness of the material forming the dishes. The support provided by the abutting support regions also causes the edges of the rims of stacked dishes to be separated by a space so that the dishes can be easily separated when needed.

Abstract: A deployable satellite antenna system permits an antenna with elevation and azimuth control to be mounted to the roof of a vehicle. The elevation control assembly for the antenna system has a base with two parallel tracks and a slider that moves along these tracks. The antenna reflector is connected to a support frame pivotably attached to the slider. Pivot arms are pivotally attached between the reflector and the base adjacent to the parallel tracks. The elevational position of the antenna is adjusted by a motor that controls the position of the slider along the parallel tracks between a stowed position in which the reflector is stowed facing the vehicle and a deployed position in which the reflector is rotated to a maximum elevational angle. In one embodiment, a feed arm supporting the feed horn extends outward from the antenna support frame adjacent to the lower edge of the antenna.

Abstract: A deployable satellite antenna system permits an antenna with elevation control to be mounted. The elevation control assembly for the antenna system has a base with two parallel tracks and a slider that moves along these tracks. The antenna is connected to a support frame pivotally attached to the slider. Pivot arms are pivotally attached between the reflector and the base adjacent to the parallel tracks. The elevational position of the antenna is adjusted by a motor that controls the position of the slider along the parallel tracks between a stowed position in which the antenna is stowed facing the vehicle and a deployed position in which the antenna is rotated to a maximum elevational angle.

Abstract: A self-locking housing for an electronic circuit such as a power supply. The self-locking housing includes a printed circuit board carrying an electronic circuit, a bottom housing half, and a top housing half. The bottom housing half has locator tabs placed at one end for holding one end of the printed circuit board in a predetermined position within the interior of the bottom housing. Opposing support tabs are placed at the other end and side support tabs are provided on the side of the bottom housing. The support tabs support the printed circuit board in the bottom housing. Bottom snaps are provided on opposing sides of the bottom housing, and the printed circuit board abuts against the bottom snaps. The top housing has corresponding opposing grooves so that when the top housing is placed over the bottom housing the snaps in the bottom housing snap into the grooves so as to self-lock with the top housing.

Abstract: A satellite receiver having first and second stages that are serially coupled so that an output of the first stage feeds into an input of the second stage is provided. Each of the first and second stages includes a tunable oscillator for providing a reference frequency, a means coupled to the input and the tunable oscillator for mixing a frequency modulated (FM) signal on that stage's input with the reference frequency to provide an intermediate frequency (IF) FM signal, and a bandpass filter for filtering the IF FM signal and providing the filtered IF FM signal to that stage's output.

Abstract: A conical corrugated microwave feed horn. A conical flare section is formed at the aperture of the feed horn and a second smooth cylindrical section is formed at the throat of the feed horn. The conical flare section is formed with two regions. The first region is a corrugated conical region formed at the aperture and having a plurality of slots formed parallel to the central axis of the feed horn. Each slot in the plurality of slots has an inner surface closest to the central axis of the feed horn and an outer surface furthest from the central axis. Connecting the corrugated conical region to the cylindrical throat is a smooth conical region. The first slot adjacent the smooth conical region has first and second formed lips on the terminating end thereof. The lips are formed directed inwardly toward each other. The last slot of the plurality of slots at the aperture of the feed horn has the terminating end of the inner surface extending in length beyond the length of the outer surface.

Abstract: A receiver connected to the satellite dish antenna receives signals from an electronic compass for generating a magnetic direction signal. The approximate latitude and longitude values of the parked vehicle are displayed and the user of the system manually selects the latitude and longitude coordinates corresponding to the parked vehicle location. The receiver determines an initial search position for the satellite dish antenna based upon the magnetic reading and the entered latitude and longitude values. The satellite dish antenna is moved from an unstowed position to an initial search position. The satellite dish antenna is then moved in a first rectangular spiral search pattern to obtain a rough-tune position corresponding to the detection of a signal peak for a selected audio subcarrier frequency in a selected channel of a target satellite. The frequency selected is not present in corresponding selected channels of satellites near the target satellite.

Abstract: A system is described for raising and lowering an antenna without using an electric motor or hand crank. A shaft is attached to an antenna mounted to the roof of a recreational vehicle. A first adapter engages the shaft. A second adapter couples with the first adapter. A portable self-powered activating device such as an electric screwdriver is secured by a chuck to the second adapter. The rotational force generated by the activating device is transferred via the first and second adapters to the shaft to raise or lower the antenna.

Abstract: A deployable satellite antenna system permits an antenna with elevation and azimuth control to be mounted to the roof of a vehicle. The elevation control assembly for the antenna system has a base with two parallel tracks and a slider that moves along these tracks. The antenna is connected to a support frame pivotally attached to the slider. Pivot arms are pivotally attached between the reflector and the base adjacent to the parallel tracks. The elevational position of the antenna is adjusted by a motor that controls the position of the slider along the parallel tracks between a stowed position in which the antenna is stowed facing the vehicle and a deployed position in which the antenna is rotated to a maximum elevational angle. The azimuth of the antenna is controlled by a rotating assembly mounted to the roof of the vehicle beneath the base of the elevation control assembly.