A smart globe includes: a sphere having a hollow interior; a projection module configured to form a projection image on an inner surface of the sphere; and a processor electrically coupled to the projection module and configured to control the projection module based on received location information, to have the projection module display geographic information corresponding to the location information. User interact with the globe can be realized through physical operations of the smart globe.

A smart globe includes: a sphere having a hollow interior; a projection module configured to form a projection image on an inner surface of the sphere; and a processor electrically coupled to the projection module and configured to control the projection module based on received location information, to have the projection module display geographic information corresponding to the location information. User interact with the globe can be realized through physical operations of the smart globe.

An apparatus (100) for performing spherical geometry is disclosed. The apparatus (100) includes a frame (102) having a base (104) and a sphere set (106) placed on the base (104). The sphere set (106) includes an outer sphere (108) having a transparent surface and an inner sphere (110) having a surface representing a graph template, which includes azimuth and polar angle scales. The inner sphere (110) is held in a default static orientation with reference to the base (104) and is concentric with reference to the outer sphere (108) by a levitating arrangement. The outer sphere (108) is supported on the base (104) and is rotatable in any direction independent of the inner sphere (108) for determining spherical geometry measurements based on the graph template.

Implemented is a smart touch screen globe that sits on top of a stand. The stand has its own secondary display device that enables a user to control some of the features of the touch screen globe. The upper part of the stand has a vent to enable airflow throughout the device and globe and reduce heat within the device. The stand's base is slightly larger than the globe itself to accommodate the globe's weight and size better and thereby maintain the device's sturdiness. The stand is configured with various components and electronics, including Bluetooth, Wi-Fi, USB (Universal Serial Bus) ports, microphone, speaker, power ports, internal compass, battery, among other components.

A self-rotating display device (1) includes and outer light transmissive container (2) containing a light transmissive fluid (6) and a body (4) containing an electric motor (14) for rotating the body with respect to the outer container. The body also carries a compass magnet (18) as a source of counter-torque for the motor to operate against. A magnetic positioning structure (20) made of ferromagnetic material secured to the container interacts with the magnetic field of the compass magnet to cause the body to migrate toward a location minimizing the distance between the magnetic positioning structure and compass magnet, so that the body can remain centered within the display while rotating.

A self-rotating display device (1) includes and outer light transmissive container (2) containing a light transmissive fluid (6) and a body (4) containing an electric motor (14) for rotating the body with respect to the outer container. The body also carries a compass magnet (18) as a source of counter-torque for the motor to operate against. A magnetic positioning structure (20) made of ferromagnetic material secured to the container interacts with the magnetic field of the compass magnet to cause the body to migrate toward a location minimizing the distance between the magnetic positioning structure and compass magnet, so that the body can remain centered within the display while rotating.

A self-rotating display device (1) includes and outer light transmissive container (2) containing a light transmissive fluid (6) and a body (4) containing an electric motor (14) for rotating the body with respect to the outer container. The body also carries a compass magnet (18) as a source of counter-torque for the motor to operate against. A magnetic positioning structure (20) made of ferromagnetic material secured to the container interacts with the magnetic field of the compass magnet to cause the body to migrate toward a location minimizing the distance between the magnetic positioning structure and compass magnet, so that the body can remain centered within the display while rotating.

A self-rotating display device (1) includes and outer light transmissive container (2) containing a light transmissive fluid (6) and a body (4) containing an electric motor (14) for rotating the body with respect to the outer container. The body also carries a compass magnet (18) as a source of counter-torque for the motor to operate against. A magnetic positioning structure (20) made of ferromagnetic material secured to the container interacts with the magnetic field of the compass magnet to cause the body to migrate toward a location minimizing the distance between the magnetic positioning structure and compass magnet, so that the body can remain centered within the display while rotating.

A globe assembly and method of manufacturing a raised relief globe including laminating the at least two plastic layer sheets as the printing sheet. The plastic sheet has the longitude and transverse. Both the two layers can have the same longitudinal strength and transverse strength. When laminating, maintain the longitude of first layer same direction as the transverse of second layer, so the transverse of the first layer has the same direction as the longitude of the second layer. A map design is then printed on the flat laminating plastic sheet. The plastic sheet is formed into a substantially hemispherical shape. A mold core is positioned on the back side of the sheet. A styrene backing is molded onto the hemispherical shaped sheet. A second molded hemisphere is produced in the substantially the same manner. The two hemispheres are then assembled as the raised relief globe.

A globe assembly and method of manufacturing a raised relief globe including laminating the at least two plastic layer sheets as the printing sheet. The plastic sheet has the longitude and transverse. Both the two layers can have the same longitudinal strength and transverse strength. When laminating, maintain the longitude of first layer same direction as the transverse of second layer, so the transverse of the first layer has the same direction as the longitude of the second layer. A map design is then printed on the flat laminating plastic sheet. The plastic sheet is formed into a substantially hemispherical shape. A mold core is positioned on the back side of the sheet. A styrene backing is molded onto the hemispherical shaped sheet. A second molded hemisphere is produced in the substantially the same manner. The two hemispheres are then assembled as the raised relief globe.