Abstract: Systems and methods for responding to faults in a robotic system are provided herein. In some embodiments, the system includes an elongate body having a proximal end and a distal end, a backend housing coupled to the proximal end of the elongate body, and a control system. The backend housing includes one or more actuators configured to manipulate the distal end of the elongate body. The control system is configured to control the robotic system by performing operations including: determining an operational state of the medical robotic system, detecting a fault in one or more components of the medical robotic system, classifying the fault according to one or more heuristics, and imposing a fault reaction state on the medical robotic system based on the one or more heuristics to mitigate the fault.

Abstract: A medical robotic system includes a control system and a manipulator assembly including actuators to manipulate a flexible elongate body, including a rotation actuator to bend the flexible elongate body. The control system is configured to perform: determining an operational state of the system; detecting a fault in one or more components of the system; classifying the fault with one or more classifications of a plurality of classifications according to heuristics; and imposing a fault reaction state on the system based on the classifications to mitigate the fault. The control system is configured to impose a first fault reaction state for a motion actuation fault and impose a second fault reaction state for a non-motion actuation fault. The first fault reaction state includes controlling the rotation actuator to cause the elongate body to become compliant to external forces placed upon the elongate body by walls of an anatomical passageway.

Abstract: Systems and methods for responding to faults in a robotic system are provided herein. In some embodiments, the system includes an elongate body having a proximal end and a distal end, a backend housing coupled to the proximal end of the elongate body, and a control system. The backend housing includes one or more actuators configured to manipulate the distal end of the elongate body. The control system is configured to control the robotic system by performing operations including: determining an operational state of the medical robotic system, detecting a fault in one or more components of the medical robotic system, classifying the fault according to one or more heuristics, and imposing a fault reaction state on the medical robotic system based on the one or more heuristics to mitigate the fault.

Abstract: A solar tracking system and method that use a tube that admits solar radiation and one or more photodetectors for generating a signal related to an intensity of solar radiation at a distal end of the tube. The system has a scan unit for periodically executing a certain scan pattern in an elevation angle El and in an azimuth angle Az of the shielding tube. A processing unit in communication with the photodetector determines an on-sun orientation of the shielding tube based on a convolution of the signal obtained while executing the scan pattern with a trained convolution kernel. The on-sun orientation thus found can be used to update the orientation of one or more solar surfaces, e.g., reflective or photovoltaic surfaces.

Abstract: The present invention relates to a highly-available and fault-tolerant solar tracking system and the process required to manage such a system. A fleet of multiple, redundant mobile robots managed by a task coordinator is deployed to track solar panels in a solar farm in alignment with the sun. Each robot has a control unit for engaging with a coupler connected to one or multiple solar panels and adjusting their orientation, as well as communicating with the task coordinator to receive tasks. The task coordinator senses various events such as robot failure/deterioration, as well as various environmental conditions, and sends tasks reconciled with event types. The system is highly-available and fault-tolerant as it remains operational as long as there is one operational robot. The task coordinator assigns tasks to the mobile robots so as to optimize battery life or other factors, such as, e.g., overall maintenance costs across the fleet.

Abstract: A system and method of using differential optical signals to track the orientation of a solar surface or surfaces is proposed. Two dispersive prisms or gratings arranged in a mirror-symmetric fashion are used to decompose light into its constituent colors, and the gain of a differential amplifier circuit based on the difference of the frequencies of single color collimated light produced by the two prisms or gratings is used to maintain the on-sun orientation of the solar surface or surfaces. The invention provides for a high-precision, low-cost solar tracking system. Preferably, the signal processing and tracking of solar surfaces is performed by a mobile robot that travels to multiple solar surfaces to minimize cost.

Abstract: A solar tracking system and method that use a tube that admits solar radiation and one or more photodetectors for generating a signal related to an intensity of solar radiation at a distal end of the tube. The system has a scan unit for periodically executing a certain scan pattern in an elevation angle El and in an azimuth angle Az of the shielding tube. A processing unit in communication with the photodetector determines an on-sun orientation of the shielding tube based on a convolution of the signal obtained while executing the scan pattern with a trained convolution kernel. The on-sun orientation thus found can be used to update the orientation of one or more solar surfaces, e.g., reflective or photovoltaic surfaces.

Abstract: The present invention teaches acoustic absolute position encoders and methods for deploying the same. The encoder has a moving member with a mechanical contacting portion, and a stationary member associated with the moving member. Reed elements are mounted on the stationary member such that they are mechanically engaged by the contacting portion of the moving member as the latter moves linearly or rotates. The reed elements generate sound tones in response to transient contact with the contacting portion. A receiver receives the tones and an acoustic processing circuit determines the absolute position of the moving member based on the sound tones.

Abstract: The present invention relates to a highly-available and fault-tolerant solar tracking system and the process required to manage such a system. A fleet of multiple, redundant mobile robots managed by a task coordinator is deployed to track solar panels in a solar farm in alignment with the sun. Each robot has a control unit for engaging with a coupler connected to one or multiple solar panels and adjusting their orientation, as well as communicating with the task coordinator to receive tasks. The task coordinator senses various events such as robot failure/deterioration, as well as various environmental conditions, and sends tasks reconciled with event types. The system is highly-available and fault-tolerant as it remains operational as long as there is one operational robot. The task coordinator assigns tasks to the mobile robots so as to optimize battery life or other factors, such as, e.g., overall maintenance costs across the fleet.

Abstract: A solar tracking system and method that use a shielding tube that admits solar radiation and has an absorptive inner surface for absorbing the solar radiation that is incident on it. The system has a photodetector for generating a signal related to an intensity of solar radiation at a distal end of the shielding tube and a scan unit for periodically executing a certain scan pattern in an elevation angle El and in an azimuth angle Az of the shielding tube. A processing unit in communication with the photodetector determines an on-sun orientation of the shielding tube based on a convolution of the signal obtained while executing the scan pattern with a trained convolution kernel. The on-sun orientation thus found can be used to update the orientation of one or more solar surfaces, e.g., reflective or photovoltaic surfaces.

Abstract: A solar tracking system and method that use a shielding tube that admits solar radiation and has an absorptive inner surface for absorbing the solar radiation that is incident on it. The system has a photodetector for generating a signal related to an intensity of solar radiation at a distal end of the shielding tube and a scan unit for periodically executing a certain scan pattern in an elevation angle El and in an azimuth angle Az of the shielding tube. A processing unit in communication with the photodetector determines an on-sun orientation of the shielding tube based on a convolution of the signal obtained while executing the scan pattern with a trained convolution kernel. The on-sun orientation thus found can be used to update the orientation of one or more solar surfaces, e.g., reflective or photovoltaic surfaces.

Abstract: The present invention teaches acoustic absolute position encoders and methods for deploying the same. The encoder has a moving member with a mechanical contacting portion, and a stationary member associated with the moving member. Reed elements are mounted on the stationary member such that they are mechanically engaged by the contacting portion of the moving member as the latter moves linearly or rotates. The reed elements generate sound tones in response to transient contact with the contacting portion. A receiver receives the tones and an acoustic processing circuit determines the absolute position of the moving member based on the sound tones.