Sensed switch current control

1 . A circuit for a sensed switch, the circuit comprising: an evaluation node through which current flows from a voltage source node to the sensed switch when the sensed switch is closed; first and second control switches disposed between the voltage source node and the evaluation node to switch between first and second current paths for the current, wherein the current passes through the first control switch when flowing along the first current path, and wherein the second control switch is coupled to a control terminal of the first control switch to deactivate the first control switch and allow the current to flow through the second current path; and a plurality of passive circuit elements configured to establish first and second current levels for the current when flowing along the first and second current paths, respectively, and disposed between the voltage source node and the evaluation node in a circuit arrangement in which no current path to ground is present when the sensed switch is open. 2 . The circuit of claim 1 , wherein the plurality of passive circuit elements comprises: a first resistance disposed along the first current path to establish the first current level; and a second resistance disposed along the second current path to establish the second current level. 3 . The circuit of claim 2 , wherein the second resistance is disposed between the evaluation node and the control terminal of the first control switch to trigger activation of the first control switch to allow the current to flow along the first current path based on a voltage level at the evaluation node. 4 . The circuit of claim 1 , wherein the first current path does not include any active circuit elements between the first control switch and the evaluation node. 5 . The circuit of claim 1 , wherein the second current path does not include any active circuit elements between the control terminal of the first control switch and the evaluation node. 6 . The circuit of claim 1 , wherein the first and second current levels are wetting and sustaining current levels, respectively. 7 . The circuit of claim 1 , further comprising a comparator having an input terminal at the evaluation node to detect the state of the sensed switch based on the voltage level of the evaluation node. 8 . The circuit of claim 7 , further comprising a logic circuit coupled to the comparator, configured to be activated by a change in an output of the comparator, and comprising a drive switch disposed between the second control switch and a reference voltage, wherein the change in the output closes the drive switch. 9 . The circuit of claim 7 , further comprising a logic circuit coupled to the comparator, the logic circuit being configured to generate a control signal to activate the second control switch after a predetermined time period has elapsed. 10 . The circuit of claim 1 , wherein the plurality of passive circuit elements are not disposed in a current regulating loop arrangement. 11 . The circuit of claim 1 , wherein each of the first and second control switches comprises a respective p-channel field effect transistor (FET) device. 12 . The circuit of claim 1 , wherein the plurality of passive circuit elements further comprise a resistance disposed between the voltage source node and the control terminal of the first control switch to ensure the first control switch is deactivated while the sensed switch is open. 13 . A circuit for a sensed switch, the circuit comprising: a comparator configured to detect a state of the sensed switch and having an input terminal at an evaluation node having a voltage level representative of the state of the sensed switch and through which wetting and sustaining currents flow from a voltage source node to the sensed switch when the sensed switch is closed; first and second control switches disposed between the voltage source node and the evaluation node to switch between first and second current paths for the current, wherein the wetting current passes through the first control switch when flowing along the first current path, and wherein the second control switch is coupled to a control terminal of the first control switch to deactivate the first control switch and allow the sustaining current to flow through the second current path; a first resistance disposed along the first current path to establish a first current level for the wetting current when flowing along the first current path; and a second resistance disposed along the second current path and configured to establish a second current level for the sustaining current when flowing along the second current path, wherein the second resistance is disposed between the evaluation node and the control terminal of the first control switch to trigger activation of the first control switch to allow the wetting current to flow along the first current path based on the voltage level of the evaluation node. 14 . The circuit of claim 13 , wherein the first and second resistances are disposed in a circuit arrangement in which no current path to ground is present when the sensed switch is open. 15 . The circuit of claim 13 , wherein: the first current path does not include any active circuit elements between the first control switch and the evaluation node; and the second current path does not include any active circuit elements between the control terminal of the first control switch and the evaluation node. 16 . The circuit of claim 13 , further comprising a logic circuit coupled to the comparator, configured to be activated by a change in an output of the comparator, and comprising a drive switch disposed between the second control switch and a reference voltage, wherein the change in the output closes the drive switch. 17 . A method of providing wetting current for a sensed switch, the method comprising: sensing closure of the sensed switch to activate a first control switch to deliver current through the sensed switch and along a first current path at a first current level; activating a controller in response to an output of the comparator indicative of the closure of the sensed switch; and generating, with the controller, a control signal to switch the current to a second current path, wherein generating the control signal comprises activating a second control switch to deactivate the first control switch; wherein a plurality of passive circuit elements are configured to establish the first and second current levels, and wherein the plurality of passive circuit elements are disposed between a voltage source node and an evaluation node at which a comparator detects the closure of the sensed switch in a circuit arrangement in which no current path to ground is present when the sensed switch is open. 18 . The method of claim 17 , wherein the plurality of passive circuit elements comprise: a first resistance disposed along the first current path to establish the first current level; and a second resistance disposed along the second current path to establish the second current level. 19 . The method of claim 18 , wherein sensing the closure comprises sensing a voltage level at the evaluation node with the second resistance. 20 . The method of claim 17 , further comprising, upon activating the controller, initiating a timer to determine when to generate the control signal to switch the current to the second current path.