Systems, methods, and devices for health monitoring of an energy storage device

1 . A system for ultrasonic assessment of an energy storage device, the system comprising: a source array comprising ultrasound sources disposed against a first surface of the energy storage device, each ultrasound source being configured to generate and direct ultrasound into an interior volume of the energy storage device; a sensor array comprising ultrasound sensors disposed against a second surface of the energy storage device, each ultrasound sensor being configured to detect ultrasound from the interior volume of the energy storage device and to generate a response signal responsive to the detected ultrasound; a charger connected to the energy storage device and configured to charge the energy storage device, a load connected to the energy storage device and configured to discharge the energy storage device, or both the charger and the load connected to the energy storage device; and a controller configured to: control each of the ultrasound sources to generate and direct ultrasound while the energy storage device is charging via the charger or discharging via the load, control each of the ultrasound sensors to detect ultrasound while the energy storage device is charging via the charger or discharging via the load, determine a state of the energy storage device based in part upon the response signal of each of the ultrasound sensors, the determined state being a state of health, and alter the charging or the discharging based at least in part on the determined state of health, wherein a number of the ultrasound sensors in the sensor array is greater than a number of the ultrasound sources in the source array. 2 . The system of claim 1 , wherein each ultrasound source has a primary ultrasound sensor disposed against the second surface that is directly opposite to the ultrasound source and at least two secondary ultrasound sensors disposed against the second surface with the primary sensor located therebetween. 3 . The system of claim 1 , wherein a frequency of the ultrasound generated and directed into the interior volume of the energy storage device is 1 MHz or more. 4 . The system of claim 1 , wherein a frequency of the ultrasound generated and directed into the interior volume of the energy storage device is in a range of 1 MHz to 5 MHz. 5 . The system of claim 1 , wherein the controller is configured to control the ultrasound sources to generate and direct the ultrasound simultaneously. 6 . The system of claim 1 , wherein the controller is configured to control the ultrasound sources to generate and direct the ultrasound sequentially. 7 . A method for ultrasonic assessment of an energy storage device, the method comprising: disposing ultrasound sources against the energy storage device; disposing ultrasound sensors against the energy storage device, a number of the ultrasound sensors being greater than a number of the ultrasound sources; charging the energy storage device via a charger connected to the energy storage device, or discharging the energy storage device via a load connected to the energy storage device; generating and directing ultrasound into an interior volume of the energy storage device by each of the ultrasound sources while the energy storage device is charging via the charger or discharging via the load; detecting ultrasound from an interior volume of the energy storage device by each of the ultrasound sensors while the energy storage device is charging via the charger or discharging via the load; generating, by each of the ultrasound sensors, a response signal responsive to the detected ultrasound; receiving, by one or more processors, the response signal responsive to the detected ultrasound from each of the ultrasound sensors; determining, by the one or more processors, a state of the energy storage device based in part upon the response signal of each of the ultrasound sensors, the determined state being a state of health; and altering the charging or the discharging based at least in part on the determined state of health. 8 . The method of claim 7 , wherein, for each ultrasound source: a primary ultrasound sensor is disposed directly opposite to the respective ultrasound source, and at least two secondary ultrasound sensors are disposed with the primary sensor located therebetween. 9 . The method of claim 7 , wherein a frequency of the ultrasound generated and directed into the interior volume of the energy storage device is 1 MHz or more. 10 . The method of claim 7 , wherein a frequency of the ultrasound generated and directed into the interior volume of the energy storage device is in a range of 1 MHz to 5 MHz. 11 . The method of claim 7 , further comprising: receiving, by the one or more processors, a temperature measurement signal corresponding with a measured temperature of the energy storage device during the ultrasonic assessment, wherein the determining a state of the energy storage device is based in part upon the response signal of each of the ultrasound sensors and in part on the temperature measurement signal. 12 . The method of claim 7 , wherein the generating and directing ultrasound into the interior volume of the energy storage device by each of the ultrasound sources is performed simultaneously. 13 . The method of claim 7 , wherein the generating and directing ultrasound into the interior volume of the energy storage device by each of the ultrasound sources is performed sequentially. 14 . A system for ultrasonic assessment of an energy storage device, the system comprising: a first transducer array disposed against a first surface of the energy storage device, each transducer in the first transducer array being configured to generate and direct ultrasound into an interior volume of the energy storage device, to detect ultrasound reflected from the interior volume of the energy storage device, and to generate a response signal responsive to the detected ultrasound; a second transducer array disposed against a second surface of the energy storage device, each transducer in the second transducer array being configured to generate and direct ultrasound into the interior volume of the energy storage device, to detect ultrasound reflected from the interior volume of the energy storage device, and to generate a response signal responsive to the detected ultrasound; a charger connected to the energy storage device and configured to charge the energy storage device, a load connected to the energy storage device and configured to discharge the energy storage device, or both the charger and the load connected to the energy storage device; and a controller configured to: control each of the transducers in the first transducer array and in the second transducer array to generate and direct ultrasound into the interior volume of the energy storage device while the energy storage device is charging via the charger or discharging via the load, control each of the transducers in the first transducer array and in the second transducer array to detect the ultrasound reflected from the interior volume of the energy storage device while the energy storage device is charging via the charger or discharging via the load, determine a state of the energy storage device based in part upon the response signal of each of the transducers, the determined state being a state of health, and alter the charging or the discharging based at least in part on the determined state of health, wherein the transducers in the first transducer array are staggered with respect to the transducers in the second transducer array. 15 . The system of claim 14 , wher