Abstract: Dynamic industrial vehicle monitoring for modification of vehicle operator behavior comprises identifying a metric that characterizes an event associated with the operation of an industrial vehicle, the metric having at least one behavior modification action and at least one performance parameter to evaluate the event against. Monitoring operation of the industrial vehicle is carried out for the event. Upon detecting an occurrence of the event, event data is recorded that characterizes a response of a vehicle operator to the event. The recorded event data is evaluated against at least one performance parameter associated with the corresponding metric to determine whether the vehicle operator demonstrated appropriate behavior for the event. A vehicle operator score is updated based upon the evaluation and the updated vehicle operator score is communicated.

Abstract: Electronic badges are indirectly tracked by detecting, by a badge communicator on a select industrial vehicle of a fleet of industrial vehicles, the presence of an electronic badge and performing a badge logging transaction in response to detecting the electronic badge. The badge logging transaction includes receiving, by the badge communicator, a badge identifier transmitted by the detected electronic badge. The badge logging transaction also includes determining, by the badge communicator, an offset measurement of the electronic badge relative to the select industrial vehicle, electronically determining a vehicle location of the select industrial vehicle, and identifying a badge location based upon the determined vehicle location and the measured offset. The badge logging transaction can also include generating a time stamp, and wirelessly communicating a badge locator message to a remote server, the badge locator message including the badge identifier, the badge location, and the timestamp.

Abstract: Electronic badges are indirectly tracked by detecting, by a badge communicator on a select industrial vehicle of a fleet of industrial vehicles, the presence of an electronic badge and performing a badge logging transaction in response to detecting the electronic badge. The badge logging transaction includes receiving, by the badge communicator, a badge identifier transmitted by the detected electronic badge. The badge logging transaction also includes determining, by the badge communicator, an offset measurement of the electronic badge relative to the select industrial vehicle, electronically determining a vehicle location of the select industrial vehicle, and identifying a badge location based upon the determined vehicle location and the measured offset. The badge logging transaction can also include generating a time stamp, and wirelessly communicating a badge locator message to a remote server, the badge locator message including the badge identifier, the badge location, and the timestamp.

Abstract: A system for controlling an industrial vehicle comprises an information linking device, a badge communicator, an operator badge, and a controller. The controller controls the industrial vehicle operating state by identifying that an operator possessing the operator badge has approached the industrial vehicle, communicating with the server via the information linking device to authenticate the operator as authorized to operate the industrial vehicle, and pairing the operator badge with the industrial vehicle upon determining that the operator is authorized to operate the industrial vehicle. Moreover, the controller controls the industrial vehicle operating state by controlling the industrial vehicle based upon a location of the operator badge relative to the industrial vehicle.

Abstract: A process uses electronic badges to convey a condition associated with an environment to an industrial vehicle. The process comprises identifying a condition in a limited, defined environment and associating the identified condition with a badge ID. The process also comprises programming an electronic badge based upon the identified condition and positioning the electronic badge within a work area of industrial vehicles. Still further, the process comprises receiving, by a processor on an industrial vehicle, information from the electronic badge including at least one of the associated badge ID and the identified condition. The information is received via a badge communicator that communicates with electronic badges that are within a predetermined range of the industrial vehicle via a first wireless communication link. The process also determines the condition from the information from the electronic badge, and controls the industrial vehicle to take a predetermined action based upon the determined condition.

Abstract: An industrial vehicle passing maneuver is authorized by an automated process. The process comprises receiving, by a processor, a first message, a second message and a third message. The first message indicates a position of a first industrial vehicle in a work environment. The second message indicates a position of an electronic badge that is detected by the first industrial vehicle. The third message indicates a position of a second industrial vehicle within the work environment. The processor determines that the second industrial vehicle intends to pass the first industrial vehicle, and determines an instruction comprising a select one of an instruction related to a passing maneuver or an instruction not to pass based upon the position of the first industrial vehicle, the position of the electronic badge, and the position of the second industrial vehicle. The instruction is communicated to the second industrial vehicle.

Abstract: A system for controlling an industrial vehicle comprises an information linking device, a badge communicator, an operator badge, and a controller. The controller controls the industrial vehicle operating state by identifying that an operator possessing the operator badge has approached the industrial vehicle, communicating with the server via the information linking device to authenticate the operator as authorized to operate the industrial vehicle, and pairing the operator badge with the industrial vehicle upon determining that the operator is authorized to operate the industrial vehicle. Moreover, the controller controls the industrial vehicle operating state by controlling the industrial vehicle based upon a location of the operator badge relative to the industrial vehicle.

Abstract: In location-based geo-feature implementations, messages for conveyance on an industrial vehicle are determined based on a current operating state of the industrial vehicle, information about a zone with expected operating conditions, and the industrial vehicle's location. When the industrial vehicle enters the zone, the current operating state of the industrial vehicle is compared to the expected operating state, which determines the message for display. Further, the current operating state may change the way the message is displayed. In vehicle-based implementations, vehicle data is collected and analyzed to generate messages upon the triggering of predetermined events. The detection of an event can be combined with vehicle position data to create an event record that captures location. Tools are also provided for setting up, managing and using the above capabilities.

Abstract: A materials handling vehicle includes an operator platform from which an operator can drive the vehicle; a traction control system for advancing the vehicle across a floor surface; at least one sensor configured to detect the presence of an object located at a position proximate to the vehicle; and a controller communicably coupled to the at least one sensor and the traction control system. The controller is responsive to the output of the at least one sensor to stop or slow down the vehicle if an object is detected proximate to the vehicle and the vehicle is traveling in response to a remote travel request. However, the controller does not slow down or stop the vehicle if an object is proximate to the vehicle while the operator is driving the vehicle on the operator platform.

Abstract: In location-based geo-feature implementations, messages for conveyance on an industrial vehicle are determined based on a current operating state of the industrial vehicle, information about a zone with expected operating conditions, and the industrial vehicle's location. When the industrial vehicle enters the zone, the current operating state of the industrial vehicle is compared to the expected operating state, which determines the message for display. Further, the current operating state may change the way the message is displayed. In vehicle-based implementations, vehicle data is collected and analyzed to generate messages upon the triggering of predetermined events. The detection of an event can be combined with vehicle position data to create an event record that captures location. Tools are also provided for setting up, managing and using the above capabilities.

Abstract: A materials handling vehicle includes an operator platform from which an operator can drive the vehicle; a traction control system for advancing the vehicle across a floor surface; at least one sensor configured to detect the presence of an object located at a position proximate to the vehicle; and a controller communicably coupled to the at least one sensor and the traction control system. The controller is responsive to the output of the at least one sensor to stop or slow down the vehicle if an object is detected proximate to the vehicle and the vehicle is traveling in response to a remote travel request. However, the controller does not slow down or stop the vehicle if an object is proximate to the vehicle while the operator is driving the vehicle on the operator platform.

Abstract: A system for controlling an industrial vehicle comprises an information linking device, a badge communicator, an operator badge, and a controller. The controller controls the industrial vehicle operating state by identifying that an operator possessing the operator badge has approached the industrial vehicle, communicating with the server via the information linking device to authenticate the operator as authorized to operate the industrial vehicle, and pairing the operator badge with the industrial vehicle upon determining that the operator is authorized to operate the industrial vehicle. Moreover, the controller controls the industrial vehicle operating state by controlling the industrial vehicle based upon a location of the operator badge relative to the industrial vehicle.

Abstract: An industrial vehicle passing maneuver is authorized by an automated process. The process comprises receiving, by a processor, a first message, a second message and a third message. The first message indicates a position of a first industrial vehicle in a work environment. The second message indicates a position of an electronic badge that is detected by the first industrial vehicle. The third message indicates a position of a second industrial vehicle within the work environment. The processor determines that the second industrial vehicle intends to pass the first industrial vehicle, and determines an instruction comprising a select one of an instruction related to a passing maneuver or an instruction not to pass based upon the position of the first industrial vehicle, the position of the electronic badge, and the position of the second industrial vehicle. The instruction is communicated to the second industrial vehicle.

Abstract: A process uses electronic badges to convey a condition associated with an environment to an industrial vehicle. The process comprises identifying a condition in a limited, defined environment and associating the identified condition with a badge ID. The process also comprises programming an electronic badge based upon the identified condition and positioning the electronic badge within a work area of industrial vehicles. Still further, the process comprises receiving, by a processor on an industrial vehicle, information from the electronic badge including at least one of the associated badge ID and the identified condition. The information is received via a badge communicator that communicates with electronic badges that are within a predetermined range of the industrial vehicle via a first wireless communication link. The process also determines the condition from the information from the electronic badge, and controls the industrial vehicle to take a predetermined action based upon the determined condition.

Abstract: Electronic badges are indirectly tracked by detecting, by a badge communicator on a select industrial vehicle of a fleet of industrial vehicles, the presence of an electronic badge and performing a badge logging transaction in response to detecting the electronic badge. The badge logging transaction includes receiving, by the badge communicator, a badge identifier transmitted by the detected electronic badge. The badge logging transaction also includes determining, by the badge communicator, an offset measurement of the electronic badge relative to the select industrial vehicle, electronically determining a vehicle location of the select industrial vehicle, and identifying a badge location based upon the determined vehicle location and the measured offset. The badge logging transaction can also include generating a time stamp, and wirelessly communicating a badge locator message to a remote server, the badge locator message including the badge identifier, the badge location, and the timestamp.

Abstract: Dynamic industrial vehicle monitoring for modification of vehicle operator behavior comprises identifying a metric that characterizes an event associated with the operation of an industrial vehicle, the metric having at least one behavior modification action and at least one performance parameter to evaluate the event against. Monitoring operation of the industrial vehicle is carried out for the event. Upon detecting an occurrence of the event, event data is recorded that characterizes a response of a vehicle operator to the event. The recorded event data is evaluated against at least one performance parameter associated with the corresponding metric to determine whether the vehicle operator demonstrated appropriate behavior for the event. A vehicle operator score is updated based upon the evaluation and the updated vehicle operator score is communicated.

Abstract: Dynamic industrial vehicle monitoring for modification of vehicle operator behavior comprises identifying a metric that characterizes an event associated with the operation of an industrial vehicle, the metric having at least one behavior modification action and at least one performance parameter to evaluate the event against. Monitoring operation of the industrial vehicle is carried out for the event. Upon detecting an occurrence of the event, event data is recorded that characterizes a response of a vehicle operator to the event. The recorded event data is evaluated against at least one performance parameter associated with the corresponding metric to determine whether the vehicle operator demonstrated appropriate behavior for the event. A vehicle operator score is updated based upon the evaluation and the updated vehicle operator score is communicated.

Abstract: A computer implemented process is carried out by identifying a metric that characterizes an event associated with the operation of an industrial vehicle. Information about the metric is transmitted to an industrial vehicle. Further, the process includes receiving event data that characterizes a response of the industrial vehicle to the event. The process also includes updating a score for the instance of the metric associated with the vehicle operator by deriving a raw score value based upon the received event data, aggregating the derived raw score value to previously derived raw scores for the metric, and computing a modified score by applying a filter to the aggregate of raw score values. The process also includes comparing the computed modified score with a predetermined modification criteria, and sending a command back to the industrial vehicle to modify the industrial vehicle based upon the comparison.

Abstract: A materials handling vehicle includes a power unit, a load handling assembly, at least one first obstacle detector, and at least one second obstacle detector. The at least one first obstacle detector is mounted at a first location on the power unit to detect an object located along a path of travel of the power unit beyond a non-detect zone of the at least one first obstacle detector. The at least one second obstacle detector is mounted at a second location on the power unit, spaced from the first location in a first direction, and is capable of detecting an object in the non-detect zone of the at least one first obstacle detector.

Abstract: In location-based geo-feature implementations, messages for conveyance on an industrial vehicle are determined based on a current operating state of the industrial vehicle, information about a zone with expected operating conditions, and the industrial vehicle's location. When the industrial vehicle enters the zone, the current operating state of the industrial vehicle is compared to the expected operating state, which determines the message for display. Further, the current operating state may change the way the message is displayed. In vehicle-based implementations, vehicle data is collected and analyzed to generate messages upon the triggering of predetermined events. The detection of an event can be combined with vehicle position data to create an event record that captures location. Tools are also provided for setting up, managing and using the above capabilities.