Reverse current protection for a switching unit

1 . A circuit comprising: a switching unit comprising a first node, a second node, a control node, and a body, wherein the switching unit is configured to selectively couple the first node of the switching unit and the second node of the switching unit in response to receiving a control signal at the control node of the switching unit; and a reverse current protection unit configured to reduce a current flow from the second node of the switching unit to the first node of the switching unit, wherein the reverse current protection unit selectively couples the first node of the switching unit to the body of the switching unit and selectively couples the second node of the switching unit to the body of the switching unit. 2 . The circuit according to claim 1 , wherein the reverse current protection unit couples the second node of the switching unit to the body of the switching unit in response to a voltage of the second node of the switching unit being greater than a voltage of the first node of the switching unit. 3 . The circuit according to claim 1 , further comprising: a voltage rail coupled to the first node of the switching unit; a ground rail; and a load circuit comprising a first node coupled to the second node of the switching unit and a second node coupled to the ground rail, wherein the reverse current protection unit is configured to reduce a current flow from the load circuit to the voltage rail. 4 . The circuit according to claim 3 , wherein the reverse current protection unit comprises: a first resistive element comprising a first node and a second node, the second node of the first resistive element being coupled to the ground rail; and a first transistor comprising an emitter coupled to the first node of the switching unit, a collector coupled to the body of the switching unit, and a base coupled to the first node of the first resistive element. 5 . The circuit according to claim 4 , wherein the reverse current protection unit further comprises: a second resistive element comprising a first node coupled to the first node of the switching unit and a second node; and a second transistor comprising an emitter coupled to the second node of the switching unit, a collector coupled to the body of the switching unit, and a base coupled to the second node of the second resistive element. 6 . The circuit according to claim 5 , wherein the reverse current protection unit further comprises: a third transistor comprising an emitter coupled to the ground rail, a collector coupled to the body of the switching unit, and a base coupled to the second node of the second resistive element. 7 . The circuit according to claim 6 , wherein the reverse current protection unit couples the body of the switching unit and the ground rail in response to a voltage of the ground rail being greater than a voltage of the voltage rail. 8 . The circuit according to claim 3 , wherein the switching unit is further configured to operate in a closed state and an open state, wherein during the closed state the switching unit permits current to flow bi-directionally between the first node of the switching unit and the second node of the switching unit and wherein during the open state the switching unit reduces current flow between the first node of the switching unit and the second node of the switching unit. 9 . The circuit according to claim 8 , comprising: a driver unit configured to generate the control signal received at the control node of the switching unit to cause the switching unit to operate in the open state when a voltage of the first node of the load circuit is greater than a voltage of the voltage rail. 10 . The circuit according to claim 9 , wherein the driver unit is further configured to generate the control signal received at the control node of the switching unit to cause the switching unit to operate in the open state when a voltage of the ground rail is greater than a voltage of the voltage rail. cm 11 . An integrated circuit comprising: a driver unit configured to receive an input signal on an input node of the integrated circuit and to generate a control signal in response to the input signal received on the input node; a switching unit comprising a first node coupled to a voltage rail of the integrated circuit, a second node coupled to an output node of the integrated circuit, and a body, wherein the switching unit is configured to selectively couple the first node of the switching unit and the second node of the switching unit in response to the control signal generated by the driver unit; and a reverse current protection unit configured to reduce a current flow from the second node of the switching unit to the first node of the switching unit, wherein the reverse current protection unit selectively couples the first node of the switching unit to the body of the switching unit and selectively couples the second node of the switching unit to the body of the switching unit. 12 . The integrated circuit according to claim 11 , wherein: the reverse current protection unit selectively couples a ground rail of the integrated circuit to the body of the switching unit. 13 . The integrated circuit according to claim 12 , wherein: the reverse current protection unit couples the body of the switching unit and the ground rail in response to a voltage of the ground rail being greater than a voltage of the first node of the switching unit. 14 . The integrated circuit according to claim 11 , wherein: the driver unit is configured to compare a voltage of the voltage rail with a voltage of the output node, and the driver unit generates the control signal further in response to the comparison of the voltage of the voltage rail with the voltage of the output node. 15 . The integrated circuit according to claim 14 , wherein the driver unit generates the control signal to operate the switching unit in an open state when the voltage of the output node is greater than the voltage of the voltage rail, wherein during the open state the switching unit reduces current flow between the voltage rail and the output node. 16 . The integrated circuit according to claim 15 , wherein the driver unit is further configured to generate the control signal received at the control node of the switching unit to cause the switching unit to operate in the open state when a voltage of a ground rail of the integrated circuit is greater than a voltage of the voltage rail. 17 . A semiconductor device comprising: means for selectively coupling a first node of a switching unit and a second node of the switching unit in response to a control signal; and means for switching a body of the switching unit to reduce a current flow from the second node of the switching unit to the first node of the switching unit. 18 . The semiconductor device according to claim 17 , comprising: means for generating the control signal. 19 . The semiconductor device according to claim 17 , comprising: means for discharging a current from the second node of the switching unit to a ground rail of the semiconductor device. 20 . The semiconductor device according to claim 19 , comprising: means for coupling the body of the switching unit and the ground rail in response to a voltage of the ground rail being greater than a voltage of the first node of the switching unit.