A fishing apparatus and a method for controlling the same. The fishing apparatus includes: a fishing rod having a reel and a motor connected with the reel; a brainwave collection unit arranged to collect a brainwave signal from a user of the fishing apparatus; and a control unit arranged to receive the brainwave signal collected by the brainwave collection unit. The apparatus generates a motor control signal according to the brainwave signal and transmits the motor control signal to the motor. The motor drives the reel to rotate under the control of the motor control signal. The fishing apparatus and the method for controlling the same as provided by the present disclosure are easy to use and labor-saving.

A fishing apparatus and a method for controlling the same. The fishing apparatus includes: a fishing rod having a reel and a motor connected with the reel; a brainwave collection unit arranged to collect a brainwave signal from a user of the fishing apparatus; and a control unit arranged to receive the brainwave signal collected by the brainwave collection unit. The apparatus generates a motor control signal according to the brainwave signal and transmits the motor control signal to the motor. The motor drives the reel to rotate under the control of the motor control signal. The fishing apparatus and the method for controlling the same as provided by the present disclosure are easy to use and labor-saving.

A control system may control multiple devices, such as jacks. The control system may adjust the speeds of the devices based on their distances from associated targets. The control system improves overall walking system performance by more efficiently directing more of the limited resources, such as hydraulic fluid, to the furthest back jacks.

A control system may control multiple devices, such as jacks. The control system may adjust the speeds of the devices based on their distances from associated targets. The control system improves overall walking system performance by more efficiently directing more of the limited resources, such as hydraulic fluid, to the furthest back jacks.

A method, computer system, and computer readable medium for facilitating selection from a plurality of devices, each device defined by a selection range dependent on at least a first parameter and a second parameter, the first parameter and the second parameter being correlated. The method includes: displaying on a graphical interface screen a graph of the first parameter versus the second parameter, the graph having displayed thereon a plurality of regions representing the selection ranges, receiving selection of at least a point of the graph from an indicator overlaid onto the graph and which is moveable on the graphical interface screen based on control from an input device, and in response to the selection, displaying on the graph only the regions which are relevant to the selected point.

A method, computer system, and computer readable medium for facilitating selection from a plurality of devices, each device defined by a selection range dependent on at least a first parameter and a second parameter, the first parameter and the second parameter being correlated. The method includes: displaying on a graphical interface screen a graph of the first parameter versus the second parameter, the graph having displayed thereon a plurality of regions representing the selection ranges, receiving selection of at least a point of the graph from an indicator overlaid onto the graph and which is moveable on the graphical interface screen based on control from an input device, and in response to the selection, displaying on the graph only the regions which are relevant to the selected point.

A method is provided for operating a materials handling vehicle comprising: monitoring, by a processor, vehicle acceleration in a direction of travel of the vehicle during a manual operation by an operator of the vehicle when the vehicle is traveling in a first vehicle orientation; collecting and storing, by the processor, data related to the monitored vehicle acceleration; receiving, by the processor, a request to implement a semi-automated driving operation; calculating, by the processor, a maximum vehicle acceleration based on acceleration data comprising the stored data, wherein the data related to the monitored vehicle acceleration used in calculating the maximum vehicle acceleration comprises only the vehicle acceleration data in the direction of travel of the vehicle collected when the vehicle is traveling in the first vehicle orientation. Based at least in part on the maximum vehicle acceleration, controlling, by the processor, implementation of the semi-automated driving operation.

A method is provided for operating a materials handling vehicle comprising: monitoring, by a processor, vehicle acceleration in a direction of travel of the vehicle during a manual operation by an operator of the vehicle when the vehicle is traveling in a first vehicle orientation; collecting and storing, by the processor, data related to the monitored vehicle acceleration; receiving, by the processor, a request to implement a semi-automated driving operation; calculating, by the processor, a maximum vehicle acceleration based on acceleration data comprising the stored data, wherein the data related to the monitored vehicle acceleration used in calculating the maximum vehicle acceleration comprises only the vehicle acceleration data in the direction of travel of the vehicle collected when the vehicle is traveling in the first vehicle orientation. Based at least in part on the maximum vehicle acceleration, controlling, by the processor, implementation of the semi-automated driving operation.

A vortex-producing fan controller uses a variable-speed vortex-producing fan positioned above a server rack to create a helical airflow within the server rack that couples with cooled air entering a data center through a floor opening situated near a bottom of the server rack. A speed of the variable-speed vortex-producing fan and a flow rate of the cooled air coupled within the helical airflow up through the server rack are adjusted responsive to changes in input air temperature of air entering the variable-speed vortex-producing fan detected using a fan input air temperature sensor positioned above the server rack.

A vortex-producing fan controller uses a variable-speed vortex-producing fan positioned above a server rack to create a helical airflow within the server rack that couples with cooled air entering a data center through a floor opening situated near a bottom of the server rack. A speed of the variable-speed vortex-producing fan and a flow rate of the cooled air coupled within the helical airflow up through the server rack are adjusted responsive to changes in input air temperature of air entering the variable-speed vortex-producing fan detected using a fan input air temperature sensor positioned above the server rack.