Abstract: A method of populating a digital environment with an anonymous humanoid digital character is disclosed. One or more values are randomly determined for one or more target human properties. An asset pool is searched for assets that are compatible with the one or more values. The assets include a human body mesh. A blend of height and weight vertex animation textures (VATs) is applied to the human body mesh. The blended human body mesh is placed into the digital environment.

Abstract: The field of the invention relates to bicycle systems, especially to bicycle systems adapted for use with smartphones, to smartphones configured for use with bicycle systems, and to methods and to computer software for use with such bicycle systems or smartphones, and to servers configured to communicate with such bicycle systems or smartphones. According to a first aspect of the invention, there is provided a bicycle system including a bicycle, the bicycle system including a processor integral to the bicycle, the bicycle system further including a battery integral to the bicycle, wherein the processor is powerable by the battery, the bicycle system including a smartphone holder configurable to receive a smartphone and to connect the smartphone to the processor, wherein in use the smartphone holder is attachable to, and detachable from, the smartphone.

Abstract: The field of the invention relates to bicycle systems, especially to bicycle systems adapted for use with smartphones, to smartphones configured for use with bicycle systems, and to methods and to computer software for use with such bicycle systems or smartphones, and to servers configured to communicate with such bicycle systems or smartphones. According to a first aspect of the invention, there is provided a bicycle system including a bicycle, the bicycle system including a processor integral to the bicycle, the bicycle system further including a battery integral to the bicycle, wherein the processor is powerable by the battery, the bicycle system including a smartphone holder configurable to receive a smartphone and to connect the smartphone to the processor, wherein in use the smartphone holder is attachable to, and detachable from, the smartphone.

Abstract: The field of the invention relates to bicycle systems, especially to bicycle systems adapted for use with smartphones, to smartphones configured for use with bicycle systems, and to methods and to computer software for use with such bicycle systems or smartphones, and to servers configured to communicate with such bicycle systems or smartphones. According to a first aspect of the invention, there is provided a bicycle system including a bicycle, the bicycle system including a processor integral to the bicycle, the bicycle system further including a battery integral to the bicycle, wherein the processor is powerable by the battery, the bicycle system including a smartphone holder configurable to receive a smartphone and to connect the smartphone to the processor, wherein in use the smartphone holder is attachable to, and detachable from, the smartphone.

Abstract: The field of the invention relates to bicycle systems, especially to bicycle systems adapted for use with smartphones, to smartphones configured for use with bicycle systems, and to methods and to computer software for use with such bicycle systems or smartphones, and to servers configured to communicate with such bicycle systems or smartphones. According to a first aspect of the invention, there is provided a bicycle system including a bicycle, the bicycle system including a processor integral to the bicycle, the bicycle system further including a battery integral to the bicycle, wherein the processor is powerable by the battery, the bicycle system including a smartphone holder configurable to receive a smartphone and to connect the smartphone to the processor, wherein in use the smartphone holder is attachable to, and detachable from, the smartphone.

Abstract: A robotic vehicle (10,100,150A,150B150C,160,1000,1000A,1000B,1000C) includes a chassis (20,106,152,162) having front and rear ends (20A,152A,20B,152B) and supported on right and left driven tracks (34,44,108,165). Right and left elongated flippers (50,60,102,154,164) are disposed on corresponding sides of the chassis and operable to pivot. A linkage (70,156,166) connects a payload deck assembly (D1,D2,D3,80,158,168,806), configured to support a removable functional payload, to the chassis. The linkage has a first end (70A) rotatably connected to the chassis at a first pivot (71), and a second end (70B) rotatably connected to the deck at a second pivot (73). Both of the first and second pivots include independently controllable pivot drivers (72,74) operable to rotatably position their corresponding pivots (71,73) to control both fore-aft position and pitch orientation of the payload deck (D1,D2,D3,80,158,168,806) with respect to the chassis (20,106,152,162).

Abstract: A method is provided for mounting a plurality of cable connectors onto a panel that defines a plurality of target mounting locations. At least two of the plurality of cable connectors defines at least a pair of cable retaining apertures. The pairs of cable retaining apertures of a first one of the two cable connectors are spaced apart in a first direction, and the pair of cable retaining apertures of a second one of the two cable connectors are spaced apart in a second direction that is different than the first direction.

Abstract: The field of the invention relates to bicycle systems, especially to bicycle systems adapted for use with smartphones, to smartphones configured for use with bicycle systems, and to methods and to computer software for use with such bicycle systems or smartphones, and to servers configured to communicate with such bicycle systems or smartphones. According to a first aspect of the invention, there is provided a bicycle system including a bicycle, the bicycle system including a processor integral to the bicycle, the bicycle system further including a battery integral to the bicycle, wherein the processor is powerable by the battery, the bicycle system including a smartphone holder configurable to receive a smartphone and to connect the smartphone to the processor, wherein in use the smartphone holder is attachable to, and detachable from, the smartphone.

Abstract: A robotic vehicle (10,100,150A,150B150C,160,1000,1000A,1000B,1000C) includes a chassis (20,106,152,162) having front and rear ends (20A,152A,20B,152B) and supported on right and left driven tracks (34,44,108,165). Right and left elongated flippers (50,60,102,154,164) are disposed on corresponding sides of the chassis and operable to pivot. A linkage (70,156,166) connects a payload deck assembly (D1,D2,D3,80,158,168,806), configured to support a removable functional payload, to the chassis. The linkage has a first end (70A) rotatably connected to the chassis at a first pivot (71), and a second end (70B) rotatably connected to the deck at a second pivot (73). Both of the first and second pivots include independently controllable pivot drivers (72,74) operable to rotatably position their corresponding pivots (71,73) to control both fore-aft position and pitch orientation of the payload deck (D1,D2,D3,80,158,168,806) with respect to the chassis (20,106,152,162).

Abstract: A method is provided for mounting a plurality of cable connectors onto a panel that defines a plurality of target mounting locations. At least two of the plurality of cable connectors defines at least a pair of cable retaining apertures. The pairs of cable retaining apertures of a first one of the two cable connectors are spaced apart in a first direction, and the pair of cable retaining apertures of a second one of the two cable connectors are spaced apart in a second direction that is different than the first direction.

Abstract: A method is provided for mounting a plurality of cable connectors onto a panel that defines a plurality of target mounting locations. At least two of the plurality of cable connectors defines at least a pair of cable retaining apertures. The pairs of cable retaining apertures of a first one of the two cable connectors are spaced apart in a first direction, and the pair of cable retaining apertures of a second one of the two cable connectors are spaced apart in a second direction that is different than the first direction.

Abstract: Systems and methods for docking portable electronic devices. A master device may be docked to a slave device to control the operation of the slave device. The slave device may have a form factor different than that of the master device. For example, the slave device may be a tablet and the master device may be a handheld device such as a smart phone. The slave device may include a retention mechanism to retain the master device in a docked position with respect to the slave device. When in the docked position, the master device may be in operative communication with one or more hardware components of the slave device to control the operation thereof. The slave device may lack the ability to exploit the full functionality of the one or more hardware components of the slave device without communication with the master device.

Abstract: A robotic vehicle (10,100,150A,150B150C,160,1000,1000A,1000B,1000C) includes a chassis (20,106,152,162) having front and rear ends (20A,152A,20B,152B) and supported on right and left driven tracks (34,44,108,165). Right and left elongated flippers (50,60,102,154,164) are disposed on corresponding sides of the chassis and operable to pivot. A linkage (70,156,166) connects a payload deck assembly (D1,D2,D3,80,158,168,806), configured to support a removable functional payload, to the chassis. The linkage has a first end (70A) rotatably connected to the chassis at a first pivot (71), and a second end (70B) rotatably connected to the deck at a second pivot (73). Both of the first and second pivots include independently controllable pivot drivers (72,74) operable to rotatably position their corresponding pivots (71,73) to control both fore-aft position and pitch orientation of the payload deck (D1,D2,D3,80,158,168,806) with respect to the chassis (20,106,152,162).

Abstract: A robotic vehicle includes a chassis supported on right and left driven tracks, right and left elongated flippers disposed on corresponding sides of the chassis, and a battery unit holder disposed on the chassis for removably receiving a battery unit weighing at least 50 lbs. The battery unit holder includes a guide for receiving and guiding the battery unit to a connected position and a connector mount having locating features and communication features. The locating features receive corresponding locating features of the battery unit, as the battery unit is moved to its connected position, to align the communication features of the connector mount with corresponding communication features of the battery unit. The communication features of the connector mount are movable in a plane transverse to the guide to aid alignment of the communication features for establishment of an electrical connection therebetween when the battery unit is in its connected position.

Abstract: Systems and methods for docking portable electronic devices. A master device may be docked to a slave device to control the operation of the slave device. The slave device may have a form factor different than that of the master device. For example, the slave device may be a tablet and the master device may be a handheld device such as a smart phone. The slave device may include a retention mechanism to retain the master device in a docked position with respect to the slave device. When in the docked position, the master device may be in operative communication with one or more hardware components of the slave device to control the operation thereof. The slave device may lack the ability to exploit the full functionality of the one or more hardware components of the slave device without communication with the master device.

Abstract: A robotic vehicle (10,100,150A,150B150C,160,1000,1000A, includes a chassis (20,106,152,162) having front and rear ends (20A,152A,20B,152B) and supported on right and left driven tracks (34,44,108,165). Right and left elongated flippers (50,60,102,154,164) are disposed on corresponding sides of the chassis and operable to pivot. A linkage (70,156,166) connects a payload deck assembly (D1,D2,D3,80,158,168,806), configured to support a removable functional payload, to the chassis. The linkage has a first end (70A) rotatably connected to the chassis at a first pivot (71), and a second end (70B) rotatably connected to the deck at a second pivot (73). Both of the first and second pivots include independently controllable pivot drivers (72,74) operable to rotatably position their corresponding pivots (71,73) to control both fore-aft position and pitch orientation of the payload deck (D1,D2,D3,80,158,168,806) with respect to the chassis (20,106,152,162).

Abstract: A robotic vehicle is disclosed, which is characterized by high mobility, adaptability, and the capability of being remotely controlled in hazardous environments. The robotic vehicle includes a chassis having front and rear ends and supported on right and left driven tracks. Right and left elongated flippers are disposed on corresponding sides of the chassis and operable to pivot. A linkage connects a payload deck, configured to support a removable functional payload, to the chassis. The linkage has a first end rotatably connected to the chassis at a first pivot, and a second end rotatably connected to the deck at a second pivot. Both of the first and second pivots include independently controllable pivot drivers operable to rotatably position their corresponding pivots to control both fore-aft position and pitch orientation of the payload deck with respect to the chassis.

Abstract: A method is provided for mounting a plurality of cable connectors onto a panel that defines a plurality of target mounting locations. At least two of the plurality of cable connectors defines at least a pair of cable retaining apertures. The pairs of cable retaining apertures of a first one of the two cable connectors are spaced apart in a first direction, and the pair of cable retaining apertures of a second one of the two cable connectors are spaced apart in a second direction that is different than the first direction.

Abstract: A mobile robot includes a chassis defining at least one chassis volume and first and second sets of right and left driven flippers associated with the chassis. Each flipper has a drive wheel and defines a flipper volume adjacent to the drive wheel. The first set of flippers is disposed between the second set of flippers and the chassis. Motive power elements are distributed among the chassis volume and the flipper volumes. The motive power elements include a battery assembly, a main drive motor assembly, and a load shifting motor assembly.