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Methods, apparatuses, and computer readable medium including computer program products, are provided for determining the depth of water in a well. A method may include coupling a signal onto a cable connected to a submersible well pump. The method may further include monitoring the cable to determin

Methods, apparatuses, and computer readable medium including computer program products, are provided for determining the depth of water in a well. A method may include coupling a signal onto a cable connected to a submersible well pump. The method may further include monitoring the cable to determine a first time corresponding to a first reflection of the signal caused by the cable entering a water column between a water surface and the submersible pump. The method may further include monitoring the cable to determine a second time corresponding to a second reflection of the signal caused by an impedance mismatch between the cable surrounded by water and a motor in the submersible well pump. The method may further include determining a water height between the submersible pump and the water surface from the first time and the second time.

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1. An apparatus comprising: a monitoring circuit configured to couple between a power source and a power cable connected to a submersible well pump,wherein the monitoring circuit is configured to at least couple a signal onto the power cable, the signal comprising a voltage step,wherein the monitori

1. An apparatus comprising: a monitoring circuit configured to couple between a power source and a power cable connected to a submersible well pump,wherein the monitoring circuit is configured to at least couple a signal onto the power cable, the signal comprising a voltage step,wherein the monitoring circuit is further configured to at least monitor the power cable to determine a first time corresponding to a reduction in at least a voltage of the voltage step, the reduction based on the signal reaching a water surface above the submersible pump,wherein the monitoring circuit is further configured to at least monitor the power cable to determine a second time corresponding to an increase in at least the voltage of the voltage step, the increase based on an impedance mismatch between the power cable surrounded by water and a motor in the submersible well pump, the increase in the voltage occurring after the reduction in the voltage, andwherein the monitoring circuit is further configured to at least determine a water height between the submersible pump and the water surface from at least the first time and the second time. 2. The apparatus of claim 1, wherein the water height is determined based on at least a difference between the first time and the second time. 3. The apparatus of claim 1, wherein a cable length between a point corresponding to a launching of the signal and the water surface is determined based on at least the first time, and wherein a cable length between the point corresponding to the launching of the signal and the motor is determined based on at least the second time. 4. The apparatus of claim 1, wherein the monitoring circuit is further configured to at least generate the voltage step with an initial rising voltage duration between one and ten nanoseconds, and wherein the initial rising voltage occurs before the reduction in the voltage. 5. The apparatus of claim 1, further comprising: a removable well head cap comprising an adapter interface for connecting the removable well head cap to a water well casing at a surface level, the removable well head cap enclosing the monitoring circuit. 6. The apparatus of claim 1, wherein the monitoring circuit is further configured to provide the water height for display via a user interface. 7. The apparatus of claim 1, wherein the monitoring circuit further comprises a network interface configured to at least wirelessly transmit the water height to at least one of a user equipment or a computer. 8. The apparatus of claim 1, wherein the monitoring circuit comprises a shunt and/or current sensor electrically coupled between the power source and the power cable, and wherein the shunt and/or current sensor is configured to at least monitor current drawn by the motor over time to determine whether the motor and/or the submersible pump performance is deteriorating. 9. The apparatus of claim 1, wherein the monitoring circuit is further configured to at least determine, based on calibration, a speed of the signal propagating along the power cable providing power to the submersible pump, and wherein the monitoring circuit is further configured to at least determine the water height based on the determined speed of the signal. 10. The apparatus of claim 9, wherein the cable comprises one or more metal conductors, wherein the power cable is insulated, and wherein the speed of the signal is determined based on at least: a type of material insulating the power cable, a number of the one or more metal conductors, a medium outside of the material insulating the power cable, and whether the one or more metal conductors are twisted inside the material insulating the power cable. 11. A method comprising: coupling, by a monitoring circuit, a signal onto a power cable connected to a submersible well pump, the signal comprising a voltage step, wherein the monitoring circuit is configured to couple between a power source and the power cable;monitoring, by the monitoring circuit, the power cable to determine a first time corresponding to a reduction in at least a voltage of the voltage step, the reduction based on the signal reaching a water surface above the submersible pump;monitoring, by the monitoring circuit, the power cable to determine a second time corresponding to an increase in at least the voltage of the voltage step, the increase based on an impedance mismatch between the power cable surrounded by water and a motor in the submersible well pump, the increase in the voltage occurring after the reduction in the voltage; anddetermining, by the monitoring circuit, a water height between the submersible pump and the water surface from at least the first time and the second time. 12. The method of claim 11, wherein the water height is determined based on at least a difference between the first time and the second time. 13. The method of claim 11, wherein a cable length between a point corresponding to a launching of the signal and the water surface is determined based on at least the first time, and wherein a cable length between the point corresponding to the launching of the signal and the motor is determined based on at least the second time. 14. The method of claim 11, further comprising: generating, by the monitoring circuit, the voltage step with an initial rising voltage duration between one and ten nanoseconds, wherein the initial rising voltage occurs before the reduction in the voltage. 15. The method of claim 11, wherein the monitoring circuit is enclosed within a removable well head cap, and wherein the removable well head cap comprises an adapter interface for connecting the removable well head cap to a water well casing at a surface level. 16. The method of claim 11, further comprising: providing, via the monitoring circuit, the water height for display via a user interface. 17. The method of claim 11, further comprising: wirelessly transmitting, by a network interface forming part of the monitoring circuit, the water height to at least one of a user equipment or a computer for display via a user interface. 18. The method of claim 11, further comprising: determining, by the monitoring circuit and based on calibration, a speed of the signal propagating along the power cable providing power to the submersible pump, wherein determining the water height is based on the determined speed of the signal. 19. The method of claim 11, further comprising: monitoring, via a shunt and/or current sensor electrically coupled between the power source and the power cable, current drawn by the motor over time to determine whether the motor and/or the submersible pump performance is deteriorating, wherein the monitoring circuit comprises the shunt and/or current sensor. 20. A non-transitory computer-readable medium encoded with instructions that, when executed by at least one processor, cause operations comprising: coupling, by a monitoring circuit, a signal onto a power cable connected to a submersible well pump, the signal comprising a voltage step, wherein the monitoring circuit is configured to couple between a power source and the power cable;monitoring, by the monitoring circuit, the power cable to determine a first time corresponding to a reduction in at least a voltage of the voltage step, the reduction based on the signal reaching a water surface above the submersible pump;monitoring, by the monitoring circuit, the power cable to determine a second time corresponding to an increase in at least the voltage of the voltage step, the increase based on an impedance mismatch between the power cable surrounded by water and a motor in the submersible well pump, the increase in the voltage occurring after the reduction in the voltage; anddetermining, by the monitoring circuit, a water height between the submersible pump and the water surface from at least the first time and the second time.