Improvements in computer-based energy asset management technologies are provided. An energy asset management system with a data summarization mechanism can perform computations, for example relating to controlling the assets, which may include electric vehicles (EVs), with fewer computing resources. Further, the system can perform computations on large datasets where such computations would have otherwise been impractical with conventional systems due to the size of the data. A large dataset relating to the energy asset management system is reduced using the summarization mechanism, and a computation model is trained using the reduced dataset. Energy assets in the system may be controlled using the trained computational model. Assets may include EVs, and controlling the EVs may be based on generated predictions relating to charging interactions. The predictions may be based on road traffic information and/or weather related information. Further, the computational model may include an optimizer for scheduling charging interactions of EVs.

Systems, methods, and computer-readable media are disclosed for a systems and methods for improved LIDAR return light capture efficiency. One example method may include comparing, by a controller including a processor and at a first time, a first temperature of a first computing element to a first threshold temperature and a second temperature of a second computing element to a second threshold temperature. The example method may also include sending, based on a determination that the first temperature is below the first threshold temperature and the second temperature is above the second threshold temperature, a first signal to a switch to activate a data output corresponding to the second computing element. The example method may also include sending, to the second computing element, a second signal to cause a third computing element to increase heat dissipation from the third computing element to the first computing element. The example method may also include receiving, from the first computing element, a third temperature of the first computing element at a second time. The example method may also include comparing the third temperature of the first computing element to the first threshold temperature. The example method may also include determining that the third temperature of the first computing element is at or above the first threshold temperature at the second time. The example method may also include sending, based on a determination that that the third temperature is at or above the first threshold temperature, a third signal to the switch to activate a data output corresponding to the first computing element.

A charging station for an electric or hybrid vehicle includes at least one battery bank, a charging/discharging electronics system, at least one connection to a vehicle charging port, and an air conditioning device for heating and cooling at least one battery bank. The air conditioning device includes a refrigerant circuit for conducting a refrigerant and a coolant circuit for conducting a coolant. A control unit of the air conditioning device is configured for establishing a thermal short circuit of the coolant circuit between a heat reservoir and a cold reservoir and operating a motor of a compressor of the refrigerant circuit for as long as it takes for the waste heat of the motor fluidically connected to a space surrounding the battery bank to effectuate a temperature increase in the space to or above a predefined value.

A vehicle temperature control apparatus for controlling temperature of a temperature control object, which is at least one of inside air of a vehicle compartment and a vehicle component, includes a heat capacitive element capable of storing heat, a refrigeration cycle in which heat is absorbed from a low temperature side and is dissipated to a high temperature side, a heat exchanger that causes the heat capacitive element to exchange heat with refrigerant of the refrigeration cycle, and a heat dissipation portion which dissipates heat in the refrigerant of the refrigeration cycle to the temperature control object. Thus, a temperature control by using the heat capacitive element can be effectively performed.

Systems, methods, and computer-readable media are disclosed for a systems and methods for improved LIDAR return light capture efficiency. One example method may include comparing, by a controller including a processor and at a first time, a first temperature of a first computing element to a first threshold temperature and a second temperature of a second computing element to a second threshold temperature. The example method may also include sending, based on a determination that the first temperature is below the first threshold temperature and the second temperature is above the second threshold temperature, a first signal to a switch to activate a data output corresponding to the second computing element. The example method may also include sending, to the second computing element, a second signal to cause a third computing element to increase heat dissipation from the third computing element to the first computing element. The example method may also include receiving, from the first computing element, a third temperature of the first computing element at a second time. The example method may also include comparing the third temperature of the first computing element to the first threshold temperature. The example method may also include determining that the third temperature of the first computing element is at or above the first threshold temperature at the second time. The example method may also include sending, based on a determination that the third temperature is at or above the first threshold temperature, a third signal to the switch to activate a data output corresponding to the first computing element.

The embodiments of the present application provide a current modulation module, a parameter determination module, a battery heating system, as well as a control method and a control device thereof, and relate to the field of battery. The control method includes determining a state of charge (SOC), of the battery, modulating a first current flowing into windings of a motor into an alternating current when the SOC is greater than a first SOC threshold, so as to use heat generated by the alternating current in a first target module to heat the battery, and modulating a second current flowing into the windings of the motor into a direct current when the SOC is less than or equal to the first SOC threshold, so as to use heat generated by the direct current in a second target module to heat the battery.

A vehicle thermal energy control system that is able to achieve improved heat management in the entirety of a vehicle is provided. A thermal energy control system is provided in a vehicle and includes heat sources and a heat amount distributor configured to assign a demanded heat amount calculated from heat demands generated in the entirety of the vehicle, to each heat source on the basis of a suppliable heat amount of each heat source.

Systems, methods, and computer-readable media are disclosed for a systems and methods for improved LIDAR return light capture efficiency. One example method may include comparing, by a controller including a processor and at a first time, a first temperature of a first computing element to a first threshold temperature and a second temperature of a second computing element to a second threshold temperature. The example method may also include sending, based on a determination that the first temperature is below the first threshold temperature and the second temperature is above the second threshold temperature, a first signal to a switch to activate a data output corresponding to the second computing element. The example method may also include sending, to the second computing element, a second signal to cause a third computing element to increase heat dissipation from the third computing element to the first computing element. The example method may also include receiving, from the first computing element, a third temperature of the first computing element at a second time. The example method may also include comparing the third temperature of the first computing element to the first threshold temperature. The example method may also include determining that the third temperature of the first computing element is at or above the first threshold temperature at the second time. The example method may also include sending, based on a determination that that the third temperature is at or above the first threshold temperature, a third signal to the switch to activate a data output corresponding to the first computing element.

The embodiments of the present application provide a current modulation module, a parameter determination module, a battery heating system, as well as a control method and a control device thereof, and relate to the field of battery. The control method includes determining a state of charge (SOC), of the battery, modulating a first current flowing into windings of a motor into an alternating current when the SOC is greater than a first SOC threshold, so as to use heat generated by the alternating current in a first target module to heat the battery, and modulating a second current flowing into the windings of the motor into a direct current when the SOC is less than or equal to the first SOC threshold, so as to use heat generated by the direct current in a second target module to heat the battery.

Systems, methods, and computer-readable media are disclosed for a systems and methods for improved LIDAR return light capture efficiency. One example method may include comparing, by a controller including a processor and at a first time, a first temperature of a first computing element to a first threshold temperature and a second temperature of a second computing element to a second threshold temperature. The example method may also include sending, based on a determination that the first temperature is below the first threshold temperature and the second temperature is above the second threshold temperature, a first signal to a switch to activate a data output corresponding to the second computing element. The example method may also include sending, to the second computing element, a second signal to cause a third computing element to increase heat dissipation from the third computing element to the first computing element. The example method may also include receiving, from the first computing element, a third temperature of the first computing element at a second time. The example method may also include comparing the third temperature of the first computing element to the first threshold temperature. The example method may also include determining that the third temperature of the first computing element is at or above the first threshold temperature at the second time. The example method may also include sending, based on a determination that that the third temperature is at or above the first threshold temperature, a third signal to the switch to activate a data output corresponding to the first computing element.