Motor and controller integration for a legged robot

What is claimed is: 1. A robot comprising: a motor disposed within a housing and at a joint, wherein the joint is configured to control motion of a member of the robot; a power stage printed circuit board (PCB) disposed within the housing and including a plurality of field-effect transistors (FETs) disposed on a first surface of the power stage PCB facing the motor; a logic stage PCB including (i) one or more processors in communication with the power stage PCB, and (ii) a first rotary position sensor mounted on a surface of the logic stage PCB, wherein the surface of the logic stage PCB faces a second surface of the power stage PCB opposite the first surface, wherein the power stage PCB is disposed between the motor and the logic stage PCB, and wherein the power stage PCB and logic stage PCB are arranged on respective axially spaced planes; a shaft coupled to a rotor of the motor and configured to extend through the power stage PCB; a magnet mounted at an end of the shaft facing the first rotary position sensor; a second rotary position sensor coupled to the member of the robot and configured to provide sensor information indicative of a rotary position of the member of the robot; and a flexible PCB configured to receive one or more wires from the second rotary position sensor, and provide one or more respective wires to at least one connector configured to mate with a corresponding connector coupled to the power stage PCB. 2. The robot of claim 1 , wherein the magnet is diametrically magnetized such that as the shaft and the magnet rotate, the rotary position sensor provides information indicative of a rotary position of the shaft to the one or more processors. 3. The robot of claim 1 , further comprising: a torque sensor coupled to the housing and configured to provide torque information indicative of a torque load on the member of the robot, wherein the flexible PCB configured to receive one or more given wires from the torque sensor, and provide the one or more respective wires to the at least one connector configured to mate with the corresponding connector. 4. The robot of claim 1 , further comprising: one or more stand-offs separating the logic stage PCB from the power stage PCB and configured to provide a consistent distance therebetween. 5. A robot comprising: a motor disposed within a housing and at a joint, wherein the joint is configured to control motion of a member of the robot; a power stage printed circuit board (PCB) disposed within the housing and including a plurality of field-effect transistors (FETs) disposed on a first surface of the power stage PCB facing the motor, wherein the housing includes a thermal coupling surface protruding radially inward from an interior peripheral surface thereof between the power stage PCB and the motor; a logic stage PCB including (i) one or more processors in communication with the power stage PCB, and (ii) a rotary position sensor mounted on a surface of the logic stage PCB, wherein the surface of the logic stage PCB faces a second surface of the power stage PCB opposite the first surface, wherein the power stage PCB is disposed between the motor and the logic stage PCB, and wherein the power stage PCB and logic stage PCB are arranged on respective axially spaced planes; a shaft coupled to a rotor of the motor and configured to extend through the power stage PCB; a magnet mounted at an end of the shaft facing the rotary position sensor; a thermal sensor mounted on the first surface of the power stage PCB among the FETs and facing the motor, wherein the thermal sensor is configured to provide thermal information indicative of a temperature of the FETs and the motor to the one or more processors; and thermal interfacial material disposed between (i) the first surface of the power stage PCB to which the FETs and the thermal sensor are mounted, and (ii) the thermal coupling surface, wherein the thermal interfacial material is configured to provide for thermal transfer between the power stage PCB and the thermal coupling surface of the housing, and wherein the thermal coupling surface is configured to provide for thermal transfer from thermal interfacial material and the motor to an exterior surface of the housing. 6. The robot of claim 5 , further comprising: a plurality of heatsink fins circumferentially spaced apart in a circular array about the exterior surface of the housing. 7. The robot of claim 6 , further comprising: a fan that, when activated, is configured to direct air toward the plurality of heatsink fins; and a shroud enclosing the fan. 8. The robot of claim 5 , further comprising: one or more stand-offs separating the power stage PCB from the thermal coupling surface and configured to provide a consistent distance between the FETs and the thermal coupling surface. 9. A robot comprising: a motor disposed within a housing and at a joint, wherein the joint is configured to control motion of a member of the robot; a power stage printed circuit board (PCB) disposed within the housing and including a plurality of field-effect transistors (FETs) disposed on a first surface of the power stage PCB facing the motor; a logic stage PCB including (i) one or more processors in communication with the power stage PCB, and (ii) a rotary position sensor mounted on a surface of the logic stage PCB, wherein the surface of the logic stage PCB faces a second surface of the power stage PCB opposite the first surface, wherein the power stage PCB is disposed between the motor and the logic stage PCB, and wherein the power stage PCB and logic stage PCB are arranged on respective axially spaced planes; a shaft coupled to a rotor of the motor and configured to extend through the power stage PCB; a magnet mounted at an end of the shaft facing the rotary position sensor; and a transition board disposed between a stator of the motor and the power stage PCB, wherein the transition board is configured to receive a plurality of wires from the stator and provide a plurality of pins to the power stage PCB based on a desired type of winding connection for the motor, wherein the plurality of pins is less than the plurality of wires. 10. The robot of claim 9 , further comprising: an electric insulation sheet disposed between the transition board and the housing. 11. An assembly comprising: a motor disposed within a housing and at a joint, wherein the joint is configured to control motion of a member of a robot; a controller including (i) one or more printed circuit boards (PCBs) disposed within the housing, and (ii) a plurality of field-effect transistors (FETs) disposed on a surface of a PCB of the one or more PCBs, wherein the FETs face the motor; a first rotary position sensor mounted on the controller; a shaft coupled to a rotor of the motor and extending therefrom to the controller; a magnet mounted within the shaft at an end of the shaft facing the controllers; a second rotary position sensor coupled to the member of the robot and configured to provide information indicative of a rotary position of the member of the robot; a torque sensor coupled to the housing and configured to provide torque information indicative of a torque load on the member of the robot; and a flexible PCB configured to (i) receive one or more wires from the second rotary position sensor and the torque sensor, and (ii) provide one or more respective wires to at least one connector, wherein the at least one connector is configured to mate with a corresponding connector coupled to the controller. 12. The assembly of claim 11 , wherein the magnet is diametrically magnetized such that as the shaft and the magnet mounted therein rot