Abstract: An end effector for a robotic arm is disclosed. The end effector includes a grasping apparatus having a gripping member and an appendage extending from the gripping member forming a channel between the griping member and the appendage. The channel is configured to receive at least a portion of an article, such as a latch for a container, to be manipulated by the end effector.

Abstract: A sensor is disclosed that provides measurements in multiple degrees of freedom without significantly increasing size, complexity, or cost. The sensor can include a light component in support of a first light source operable to direct a first beam of light, and a second light source operable to direct a second beam of light. The sensor can also include an imaging device that can directly receive the first beam of light and the second beam of light and convert these into electric signals. The imaging device and the light component can be movable relative to one another. The sensor can further include a light location module and/or a position module configured to receive the electric signals and determine locations of the first beam of light, the second beam of light on the imaging device and a relative position of the imaging device and the light component.

Abstract: A hollow elongated cylinder is disclosed having a distal end and a proximal end, the proximal end configured to be removably connectable to a distal end of a syringe. An umbilical is removably inserted within said cylinder and configured for detachable connection to a data processor and a display device having a solid state imaging device disposed on a distal end of the umbilical. A lens system is disposed on a distal end of the solid state imaging device. The umbilical is inserted within the cylinder such that the distal end of the lens system is disposed at approximately the distal end of the cylinder.

Abstract: A sensor is disclosed that can include a light component in support of a first light source operable to direct a first beam of light, and a second light source operable to direct a second beam of light. The sensor can also include an imaging device positioned proximate the light component and operable to directly receive the first beam of light and the second beam of light, and convert these into electric signals. The imaging device and the light component can be movable relative to one another. The sensor can further include a light location module configured to receive the electric signals and determine locations of the first beam of light and the second. beam of light on the imaging device. In addition, the sensor can include a position. module configured to determine a relative position of the imaging device and the light component based on the locations of the first beam of light and the second beam of light on the imaging device.

Abstract: An end effector for a robotic arm is disclosed. The end effector includes a grasping apparatus having a gripping member and an appendage extending from the gripping member forming a channel between the griping member and the appendage. The channel is configured to receive at least a portion of an article, such as a latch for a container, to be manipulated by the end effector.

Abstract: Device coordinated robotic control technology is described. A network of robotic devices is established. An anthropomorphic motion is sensed from an operator. One or more signals are generated that are representative of at least a portion of the anthropomorphic motion. The one or more signals are converted into a collective set of commands to actuate the network of robotic devices. The collective set of commands is functionally equivalent to the anthropomorphic motion.

Abstract: A robotic mobile low-profile transport vehicle is disclosed. The vehicle can comprise a first transport module having a frame assembly, a mobility system, and a propulsion system and a second transport module having a frame assembly and a mobility system. A multi-degree of freedom coupling assemblage can join the first and second transport modules together. The vehicle can include a first platform supported about the frame assembly of the first transport module, and a second platform supported about the frame assembly of the second transport module. Each of the platforms can be configured to receive a load for transport. Additionally, the vehicle can include a control system that can operate to facilitate intra-module communication and coordination to provide a coordinated operating mode of the first and second transport modules and the coupling assemblage about a given terrain.

Abstract: Technology is described for qualifying a service provider. The method may include inviting the service provider to join a task allocation application that is executing using a processor. An online reference may be received from the service provider to verify a service provider's identity via an online presence. A desired territory may be received from the service provider. The territory provided by the service provider may be tested to determine whether a task is available in the territory using the processor. Schedule availability for the service provider to perform a task in the territory may be verified. The service provider may be qualified to join the task allocation application based on verifying the online references, desired territory, and schedule availability of the service provider.

Abstract: An allergy skin test device can include a support strip having a top and bottom face. An allergen can be applied to an area of the bottom face forming an allergen portion. A skin viewing portion can be located proximate or at the allergen portion. An adhesive can be applied to an area of the bottom face forming an adhesion portion. When applied to the skin of a subject, the allergy skin test device can facilitate viewing of a portion of the skin beneath the allergy skin test device through the skin viewing portion. A method of testing a subject for an allergy can include applying an allergy skin test device to the skin of the subject, recording two or more images of the skin of the subject, and electronically comparing the images.

Abstract: A method for controlling a tele-operated robot agile lift system is disclosed. The method comprises manipulating a human-machine interface of a master robot located on a mobile platform. The human machine interface is kinematically equivalent to a user's arm with a plurality of support members. A position value and a torque value is measured for each support member. The position value and torque value are communicated to support members of a kinematically equivalent slave arm to position the support members to correspond with a position of the human-machine interface.

Abstract: A catheter configured for imaging objects substantially in focus is described herein. An imaging device is disposed on the distal end of the catheter. The imaging device has an effective focal plane that is located in front of the imaging device. The catheter also includes a transparent focal instrument that has an outer periphery that is positioned at the effective focal plane of the imaging device, to enable objects in contact with the outer periphery of the transparent focal instrument to be imaged substantially in focus.

Abstract: A technology is described for sampling tasks for quality assurance. An example method may include managing a plurality of tasks assigned to and performed by service providers for customers. A sampling rate may be assigned to the plurality of tasks based on task details associated with a task, such that different tasks may have different sampling rates. The plurality of tasks may then be sampled according to the sampling rate assigned to the plurality of tasks, and a determination may be made whether to review a sampled task for quality assurance based on task analysis data after completion of the individual task.

Abstract: A sensor comprising a light component in support of a light source operable to direct a beam of light onto an imaging device having an image sensor, such as a CCD or CMOS or N-type metal-oxide-semiconductor (NMOS or Live MOS) sensor. The sensor can also comprise an imaging device positioned proximate to the light component and operable to receive the beam of light, and to convert this into an electric signal, wherein the light component and the imaging device are movable relative to one another, and wherein relative movement of the light component and the imaging device is determinable in multiple degrees of freedom. The sensor can also comprise a light deflecting module designed to deflect light from a light component onto the imaging device. The light sources and the resulting beams of light therefrom can comprise a number of different types, orientations, configurations to facilitate different measurable and determinable degrees of freedom by the sensor.

Abstract: A sensor comprising a support structure and an imaging device having an image sensor, such as a CCD or CMOS or N-type metal-oxide-semiconductor (NMOS or Live MOS) sensor, positioned proximate the support structure. The support structure and the imaging device can be movable relative to one another in at least one degree of freedom. The sensor can also comprise a fiduciary disposed about the support structure and identifiable by the imaging device, wherein a position of the fiduciary relative to the imaging device is caused to change with the relative movement of the support structure and the imaging device. A position module can be configured to determine a relative position of the imaging device and the support structure based on the position of the fiduciary relative to the imaging device.

Abstract: A method and system for gathering information from and setting up a surveillance network within an earth-surface environment that includes inserting one or more mobile robotic devices having a sensing subsystem, a communications subsystem, and a navigation subsystem into an earth-surface environment. The mobile robotic device may be configured into a traveling pose selected from a plurality of available traveling poses, and directed using the navigation subsystem to a sensing location within the earth-surface environment. The environment may be monitored and sensed information collected may be stored or communicated to a remote location. The mobile robotic device may be configured to operate with a vehicle carrier to facilitate insertion and deployment of the robotic vehicle into the earth-surface environment.

Abstract: A serpentine robotic crawler having multiple dexterous manipulators supported about multiple frame units. The frame units are connected via an articulating linkage at proximal ends wherein the articulating linkage is capable of positioning the frames into various configurations. Dexterous manipulators are coupled to distal ends of the frame units and are positionable via the articulating linkage and articulating joints therein into various positions about the frame ends. The configurations and positioning of the dexterous manipulators allows the robotic crawler to perform coordinated dexterous operations.

Abstract: A robotic mobile low-profile transport vehicle is disclosed. The vehicle can comprise a first transport module having a frame assembly, a mobility system, and a propulsion system and a second transport module having a frame assembly and a mobility system. A multi-degree of freedom coupling assemblage can join the first and second transport modules together. The vehicle can include a first platform supported about the frame assembly of the first transport module, and a second platform supported about the frame assembly of the second transport module. Each of the platforms can be configured to receive a load for transport. Additionally, the vehicle can include a control system that can operate to facilitate intra-module communication and coordination to provide a coordinated operating mode of the first and second transport modules and the coupling assemblage about a given terrain.

Abstract: A sensor is disclosed that can include a light component in support of a first light source operable to direct a first beam of light, and a second light source operable to direct a second beam of light. The sensor can also include an imaging device positioned proximate the light component and operable to directly receive the first beam of light and the second beam of light, and convert these into electric signals. The imaging device and the light component can be movable relative to one another. The sensor can further include a light location module configured to receive the electric signals and determine locations of the first beam of light and the second. beam of light on the imaging device. In addition, the sensor can include a position. module configured to determine a relative position of the imaging device and the light component based on the locations of the first beam of light and the second beam of light on the imaging device.

Abstract: An operator controllable robotic device is disclosed. The robotic device comprises a support member, an upper robotic arm, a lower robotic arm, and a control arm. The upper robotic arm is coupled to the support member and has rotational movement in at least one degree of freedom relative to the support member. The lower robotic arm is coupled to the upper robotic arm and has rotational movement in at least one degree of freedom relative to the upper robotic arm. The control arm allows an operator to control the robotic device. The control arm is coupled to the upper robotic arm and has rotational movement in at least one degree of freedom relative to the upper robotic arm. The control arm allows a movement of the operator to control a movement of at least one of the upper robotic arm and the lower robotic arm.

Abstract: A method of imaging a target using a miniaturized imaging device is disclosed comprising providing a miniaturized imaging device having a stationary lens system and an imaging array, wherein the distance from a distal end of the stationary lens system to the imaging array is fixed. The miniaturized imaging device is advanced near the desired target and a distance from a distal end of the stationary lens system to the desired target is determined. A desired wavelength of light is calculated based on the determined distance from the distal end of the stationary lens system to the desired target and the desired wavelength of light is propagated onto the target.