Included is a method for autonomous robotic refuse container replacement including: transmitting, by a processor of a first robotic refuse container, a request for replacement to a portion of processors of robotic refuse containers; receiving, by the processor of the first robotic refuse container, a return signal from a portion of processors of the robotic refuse containers; transmitting, by the processor of the first robotic refuse container, a confirmation for replacement to a processor of a second robotic refuse container in response to a return signal received from the processor of the second robotic refuse container; instructing, by the processor of the first robotic refuse container, the first robotic refuse container to navigate to a second location from a current location; and instructing, by the processor of the second robotic refuse container, the second robotic refuse container to navigate to the current location of the first robotic refuse container.

Systems and methods are provided for using video/still images captured by continuously recording optical sensors mounted on waste collection vehicles used in in the waste collection, disposal and recycling industry for operational and customer service related purposes. Optical sensors are integrated into the in-cab monitor as well as the onboard computer, digital video recorder and other external devices.

Methods and apparatuses are provided for use in monitoring product placement within a shopping facility. Some embodiments provide an apparatus configured to determine product placement conditions within a shopping facility, comprising: a transceiver configured to wirelessly receive communications; a product monitoring control circuit coupled with the transceiver; a memory coupled with the control circuit and storing computer instructions that when executed by the control circuit cause the control circuit to: obtain a composite three-dimensional (3D) scan mapping corresponding to at least a select area of the shopping facility and based on a series of 3D scan data; evaluate the 3D scan mapping to identify multiple product depth distances; and identify, from the evaluation of the 3D scan mapping, when one or more of the multiple product depth distances is greater than a predefined depth distance threshold from the reference offset distance of the product support structure.

Methods and apparatuses are provided for use in monitoring product placement within a shopping facility. Some embodiments provide an apparatus configured to determine product placement conditions within a shopping facility, comprising: a transceiver configured to wirelessly receive communications; a product monitoring control circuit coupled with the transceiver; a memory coupled with the control circuit and storing computer instructions that when executed by the control circuit cause the control circuit to: obtain a composite three-dimensional (3D) scan mapping corresponding to at least a select area of the shopping facility and based on a series of 3D scan data; evaluate the 3D scan mapping to identify multiple product depth distances; and identify, from the evaluation of the 3D scan mapping, when one or more of the multiple product depth distances is greater than a predefined depth distance threshold from the reference offset distance of the product support structure.

A system and method for verifying waste fulfillment events in the absence of human intervention using the input of one or more vehicle sensor inputs, one or more waste disposal cycle inputs, and GPS information to augment or supplement optical scanning technology such as RFID tags is disclosed.

A system and method for verifying waste fulfillment events in the absence of human intervention using the input of one or more vehicle sensor inputs, one or more waste disposal cycle inputs, and GPS information to augment or supplement optical scanning technology such as RFID tags is disclosed.

A scrambling method of data on a J1939 communication system of a vehicle involves at least moving data from one of a PGN and a PGN/SPN location to another PGN or PGN/SPN location at a first controller on the vehicle before transmitting data and then re-ordering the data at a second controller. Some embodiments further comprise encrypting data either before or after shifting, but before transmitting so as to further complicate efforts to interpret meaningful data from the transmission. The second controller may be on the vehicle or may be remotely located.

A scrambling method of data on a J1939 communication system of a vehicle involves at least moving data from one of a PGN and a PGN/SPN location to another PGN or PGN/SPN location at a first controller on the vehicle before transmitting data and then re-ordering the data at a second controller. Some embodiments further comprise encrypting data either before or after shifting, but before transmitting so as to further complicate efforts to interpret meaningful data from the transmission. The second controller may be on the vehicle or may be remotely located.

A refuse body adapter includes a sub-frame assembly, a sub-frame adapter, and a spacer. The sub-frame assembly is configured to be coupled to a cargo body. The sub-frame adapter is configured to be coupled to a chassis of a vehicle. The spacer is coupled to both the sub-frame assembly and the sub-frame adapter. The spacer is disposed in a gap formed between the sub-frame assembly and the sub-frame adapter. A thickness of the spacer may be adjusted to accommodate different gap sizes between the sub-frame assembly and the sub-frame adapter.

A refuse vehicle includes a lift assembly configured to engage and lift a refuse receptacle, an electrical energy system configured to store power and supply power to the refuse vehicle, and a controller configured to determine an amount of power required to move the refuse vehicle to a charging location, measure one or more electrical attributes of the refuse vehicle to determine an amount of length of time the refuse vehicle can operate based on a remaining power of the electrical energy system, and limit operations of one or more components of the refuse vehicle based on a comparison of the amount of power required to move the refuse vehicle to the charging location and the amount of length of time the refuse vehicle can operate.