Provided are a vehicle chassis and a vehicle, which are related to a field of vehicle technology, in particular to fields of automatic driving technology and driving test technology. The vehicle chassis includes: a chassis support, a steering system, an electrical system, a driving system, and two brake systems. The chassis support is provided with a steering system mounting site, an electrical system mounting site, a driving system mounting site, and two brake system mounting sites; which are arranged in sequence along a length direction of the vehicle chassis. A first brake system mounting site is disposed between the steering system mounting site and the electrical system mounting site; and a second brake system mounting site is disposed between the driving system mounting site and the electrical system mounting site. The two brake systems, the driving system and the steering system are communicatively connected to the electrical system.

An articulated mechanism is included in an articulated pointing system. The articulated mechanism includes first, second, and third spherical joints, and a first, second, and third lever. The first and second spherical joints are linked by the first lever. The first lever includes a first projecting portion. The first and third spherical joints are linked by the second lever, the second lever including a second projecting portion projecting in an opposite direction of the first projecting portion. The second and third spherical joints are linked by the third lever, such that the longitudinal axes of the first lever and of the second lever are perpendicular. The articulated pointing system includes a basement platform and a mobile platform joined by two articulated hinges. The hinges are moved by actuators. The articulated mechanism has the first lever attached to the mobile platform and the second lever attached to the basement platform.

An articulated mechanism is included in an articulated pointing system. The articulated mechanism includes first, second, and third spherical joints, and a first, second, and third lever. The first and second spherical joints are linked by the first lever. The first lever includes a first projecting portion. The first and third spherical joints are linked by the second lever, the second lever including a second projecting portion projecting in an opposite direction of the first projecting portion. The second and third spherical joints are linked by the third lever, such that the longitudinal axes of the first lever and of the second lever are perpendicular. The articulated pointing system includes a basement platform and a mobile platform joined by two articulated hinges. The hinges are moved by actuators. The articulated mechanism has the first lever attached to the mobile platform and the second lever attached to the basement platform.

A clip for securing a radiating arm to a printed circuit boards of a radio frequency antenna element of a base station antenna. The radiating arm may be configured to receive signals or radiate signals from a feed network associated with the at least one RF antenna member. The radiating arm can be secured to the printed circuit board without the use of solder or adhesives.

A clip for securing a radiating arm to a printed circuit boards of a radio frequency antenna element of a base station antenna. The radiating arm may be configured to receive signals or radiate signals from a feed network associated with the at least one RF antenna member. The radiating arm can be secured to the printed circuit board without the use of solder or adhesives.

The present invention provides an antenna array which includes a structure in the form of a hexagonal pyramid with a flat top surface/facet. According to preferred aspects, the pedestal support of the present invention preferably further includes six side facets which are preferably disposed 60 degrees from each other. Preferably, each side facet preferably supports a patch antenna and the top facet supports a top/zenith antenna. According to a preferred embodiment, the azimuth antennas may be offset from the ground plane by an angle between 20 and 60 degrees. The zenith antenna is preferably substantially parallel to the ground plane.

The present invention provides an antenna array which includes a structure in the form of a hexagonal pyramid with a flat top surface/facet. According to preferred aspects, the pedestal support of the present invention preferably further includes six side facets which are preferably disposed 60 degrees from each other. Preferably, each side facet preferably supports a patch antenna and the top facet supports a top/zenith antenna. According to a preferred embodiment, the azimuth antennas may be offset from the ground plane by an angle between 20 and 60 degrees. The zenith antenna is preferably substantially parallel to the ground plane.

A satellite signal acquiring apparatus includes antenna, azimuth motor, elevation motor, main body, inclination sensor and processor. Antenna receives radio wave from a communication satellite. Azimuth motor rotates the antenna in azimuth angle direction. Elevation motor changes elevation angle of the antenna. Main body is equipped with the antenna, the azimuth motor, and the elevation motor. Inclination sensor obtains inclination information of the main body. Processor corrects the elevation angle based on inclination information to hold the elevation angle of the antenna in an earth coordinate system constant regardless of an azimuth angle of the antenna. Processor acquires the communication satellite signal based on reception intensity of the radio wave.

A pedestal is provided for mounting a portable antenna onto a platform. The pedestal includes a ring, a base, a horn and a prong composed of three-dimensionally printable composite resin. The ring attaches to the platform. The base inserts into the ring and includes an outer tube having a pair of axially distributed outer holes. The horn includes an inner tube for insertion into the outer tube and an inverted pyramid that connects to the inner tube. The inner tube includes at least three axially distributed inner holes. The prong has two probes that insert into the outer holes and two of the inner holes to secure the horn to the base.

A pedestal is provided for mounting a portable antenna onto a platform. The pedestal includes a ring, a base, a horn and a prong composed of three-dimensionally printable composite resin. The ring attaches to the platform. The base inserts into the ring and includes an outer tube having a pair of axially distributed outer holes. The horn includes an inner tube for insertion into the outer tube and an inverted pyramid that connects to the inner tube. The inner tube includes at least three axially distributed inner holes. The prong has two probes that insert into the outer holes and two of the inner holes to secure the horn to the base.