Abstract: There is provided a lifting robot suitable for lifting and transferring a person. Especially there is provided a patient lift apparatus with collapsible vertical and horizontal columns that allows the apparatus to change its height and width. Specifically there is provided a patient lifting robot having a frame for lifting and carrying persons. The frame has adjustable length and width, since the frame comprises two vertically collapsible columns for adjusting the height of the frame, and one horizontally collapsible beam for adjusting the width of the frame.

Abstract: Implementations of the disclosed subject matter provide a method of receiving, at an actuated mobile device, at least one dosage level for a predetermined area, where the at least one dosage level is based on a first dosage of ultraviolet (UV) light to be output from at least one light source for at least a portion of the predetermined area. The method may include moving the actuated mobile device in a path within the predetermined area and outputting the UV light from the at least one light source onto one or more first surfaces based on the received at least one dosage level. The method may include moving the actuated mobile device within the path, and outputting the UV light onto one or more second surfaces based on the received at least one dosage level.

Abstract: Implementations of the disclosed subject matter provide a device of a mobile robot may include a motor to drive a drive system to move the mobile robot in an area, and a light source to output ultraviolet light. The device may include at least one first sensor to determine at least one of an orientation of the mobile robot, a location of the mobile robot, and/or when the light source is within a predetermined distance of an object in the area. The device may include a controller, communicatively coupled to the drive system, the light source, and the at least one first sensor to control the drive system so as to stop or move the mobile robot before the light source is within the predetermined distance of the object based on at least a signal received from the at least one first sensor.

Abstract: Implementations of the disclosed subject matter provide a mobile robot including a motor to drive a drive system to move the mobile robot in an area, a light source to output ultraviolet (UV) light, at least one sensor, a communications interface to receive at least one signal via a communications network, and a first controller to control the drive system, the light source, the at least one sensor, and the communications interface. Operations of the mobile robot may be controlled based in part on the at least one signal received via the communications network from a second controller that is in a location that is remote from the area where the mobile robot is operating.

Abstract: Implementations of the disclosed subject matter provide a method of transmitting, from a mobile robot device, sound and/or at least one image captured by a sensor to a remote user device. The mobile robot device may receive at least one first control operation for the mobile robot device to move within an area via a communications network from a remote user device. An audio signal may be transmitted based on sound received at a microphone of the mobile robot device in the area. The audio signal received from the remote user device may be output at a speaker of the mobile robot device. A volume of the audio signal output by the speaker may be adjusted based on a size of the area and on an average or a median of an amplitude of frequencies in the area based on the sound received by the microphone.

Abstract: Implementations of the disclosed subject matter provide methods of transmitting, from a first user device, an authorization to one or more other user devices to receive one or more images captured by a first sensor of a mobile robot device, where the first user device controls the mobile robot device. The first user device may receive acknowledgement from the one or more other user devices to receive the one or more images captured by the first sensor of the mobile robot device. The mobile robot device may transmit, to the first user device and the one or more other user devices based on the acknowledgement, the one or more first images captured by the first sensor of the mobile robot as the mobile robot device moves within the area based on at least one first control operation received from the first user device.

Abstract: Implementations of the disclosed subject matter provide a device of a mobile robot may include a motor to drive a drive system to move the mobile robot in an area, and a light source to output ultraviolet light. The device may include at least one first sensor to determine at least one of an orientation of the mobile robot, a location of the mobile robot, and/or when the light source is within a predetermined distance of an object in the area. The device may include a controller, communicatively coupled to the drive system, the light source, and the at least one first sensor to control the drive system so as to stop or move the mobile robot before the light source is within the predetermined distance of the object based on at least a signal received from the at least one first sensor.

Abstract: Implementations of the disclosed subject matter provide a method of moving a mobile robot within an area. The movement of the mobile robot and the emission of ultraviolet (UV) light may be stopped when a human and/or animal is determined to be within the area. Using at least one sensor, the method may be determine whether there is at least one of human identification, animal identification, motion, heat, and/or sound within the area for a predetermined period of time. When there is no human identification, animal identification, motion, heat, and/or sound within the predetermined period of time, UV light may be emitted and the drive system may be controlled to move the mobile robot within the area. When there is at least one of human identification, motion, heat, and/or sound within the predetermined period of time, a light source may be controlled to prohibit the emission of UV light.

Abstract: Implementations of the disclosed subject matter provide a method of moving, using a drive system, a mobile robot within an area. Detecting, using at least one sensor of the mobile robot, at least one of air within the area, a surface within the area, and/or an object within the area. The area may be mapped in three dimensions based on the detecting of at least one of the air, the surface, and the object as the mobile robot moves within the area. Ultraviolet (UV) light may be emitted from a light source of the mobile robot to disinfect at least a portion of the area. A representation of the emission of the UV light may be plotted onto the mapped area to generate an exposure plot, where the representation is of the UV light emitted on at least one of the air, the surface, and the object in the area.

Abstract: Implementations of the disclosed subject matter provide a method of transmitting, from a mobile robot device, sound and/or at least one image captured by a sensor to a remote user device. The mobile robot device may receive at least one first control operation for the mobile robot device to move within an area via a communications network from a remote user device. An audio signal may be transmitted based on sound received at a microphone of the mobile robot device in the area. The audio signal received from the remote user device may be output at a speaker of the mobile robot device. A volume of the audio signal output by the speaker may be adjusted based on a size of the area and on an average or a median of an amplitude of frequencies in the area based on the sound received by the microphone.

Abstract: Implementations of the disclosed subject matter provide a method of transmitting, from a mobile robot device, sound and/or at least one image captured by a sensor to a remote user device. The mobile robot device may receive at least one first control operation for the mobile robot device to move within an area via a communications network from a remote user device. An audio signal may be transmitted based on sound received at a microphone of the mobile robot device in the area. The audio signal received from the remote user device may be output at a speaker of the mobile robot device. A volume of the audio signal output by the speaker may be adjusted based on a size of the area and on an average or a median of an amplitude of frequencies in the area based on the sound received by the microphone.

Abstract: Implementations of the disclosed subject matter provide a method of transmitting, from a mobile robot device, sound and/or at least one image captured by a sensor to a remote user device. The mobile robot device may receive at least one first control operation for the mobile robot device to move within an area via a communications network from a remote user device. An audio signal may be transmitted based on sound received at a microphone of the mobile robot device in the area. The audio signal received from the remote user device may be output at a speaker of the mobile robot device. A volume of the audio signal output by the speaker may be adjusted based on a size of the area and on an average or a median of an amplitude of frequencies in the area based on the sound received by the microphone.

Abstract: Implementations of the disclosed subject matter provide methods of transmitting, from a first user device, an authorization to one or more other user devices to receive one or more images captured by a first sensor of a mobile robot device, where the first user device controls the mobile robot device. The first user device may receive acknowledgement from the one or more other user devices to receive the one or more images captured by the first sensor of the mobile robot device. The mobile robot device may transmit, to the first user device and the one or more other user devices based on the acknowledgement, the one or more first images captured by the first sensor of the mobile robot as the mobile robot device moves within the area based on at least one first control operation received from the first user device.

Abstract: Implementations of the disclosed subject matter provide a method of moving a mobile robot within an area. The movement of the mobile robot and the emission of ultraviolet (UV) light may be stopped when a human and/or animal is determined to be within the area. Using at least one sensor, the method may be determine whether there is at least one of human identification, animal identification, motion, heat, and/or sound within the area for a predetermined period of time. When there is no human identification, animal identification, motion, heat, and/or sound within the predetermined period of time, UV light may be emitted and the drive system may be controlled to move the mobile robot within the area. When there is at least one of human identification, motion, heat, and/or sound within the predetermined period of time, a light source may be controlled to prohibit the emission of UV light.

Abstract: Implementations of the disclosed subject matter provide a mobile robot including a motor to drive a drive system to move the mobile robot in an area, a light source to output ultraviolet (UV) light, at least one sensor, a communications interface to receive at least one signal via a communications network, and a first controller to control the drive system, the light source, the at least one sensor, and the communications interface. Operations of the mobile robot may be controlled based in part on the at least one signal received via the communications network from a second controller that is in a location that is remote from the area where the mobile robot is operating.

Abstract: Implementations of the disclosed subject matter provide a method of moving, using a drive system, a mobile robot within an area. Detecting, using at least one sensor of the mobile robot, at least one of air within the area, a surface within the area, and/or an object within the area. The area may be mapped in three dimensions based on the detecting of at least one of the air, the surface, and the object as the mobile robot moves within the area. Ultraviolet (UV) light may be emitted from a light source of the mobile robot to disinfect at least a portion of the area. A representation of the emission of the UV light may be plotted onto the mapped area to generate an exposure plot, where the representation is of the UV light emitted on at least one of the air, the surface, and the object in the area.

Abstract: Implementations of the disclosed subject matter provide a method of receiving, at an actuated mobile device, at least one dosage level for a predetermined area, where the at least one dosage level is based on a first dosage of ultraviolet (UV) light to be output from at least one light source for at least a portion of the predetermined area. The method may include moving the actuated mobile device in a path within the predetermined area and outputting the UV light from the at least one light source onto one or more first surfaces based on the received at least one dosage level. The method may include moving the actuated mobile device within the path, and outputting the UV light onto one or more second surfaces based on the received at least one dosage level.

Abstract: Implementations of the disclosed subject matter provide a device of a mobile robot may include a motor to drive a drive system to move the mobile robot in an area, and a light source to output ultraviolet light. The device may include at least one first sensor to determine at least one of an orientation of the mobile robot, a location of the mobile robot, and/or when the light source is within a predetermined distance of an object in the area. The device may include a controller, communicatively coupled to the drive system, the light source, and the at least one first sensor to control the drive system so as to stop or move the mobile robot before the light source is within the predetermined distance of the object based on at least a signal received from the at least one first sensor.

Abstract: There is provided a lifting robot suitable for lifting and transferring a person. Especially there is provided a patient lift apparatus with collapsible vertical and horizontal columns that allows the apparatus to change its height and width. Specifically there is provided a patient lifting robot having a frame for lifting and carrying persons. The frame has adjustable length and width, since the frame comprises two vertically collapsible columns for adjusting the height of the frame, and one horizontally collapsible beam for adjusting the width of the frame.

Abstract: A modular LED system is provided that includes a frame having a plurality of light emitting diodes (LEDs) of at least two different colors for generating light within a color spectrum. The LEDs are mounted on or adjacent to a plate equipped with cooling medium for cooling the LEDs. The system includes a processor for controlling an amount of electrical current supplied to the LEDs to determine a color of light generated by the LEDs, and a flat translucent member having translucent lenses for decreasing or increasing the diffusion angle for light emitted from each LED. The system is suitable for illuminating plants to supplement natural light without substantially interfering with the amount of natural light due to its narrow width. The system delivers uniform illumination and reduces energy and maintenance costs. The system may be installed in a commercial greenhouse.