Safety critical control system that includes control logic or machine readable instructions that selectively locks or enables the control system based on one or more machine implemented state machines that includes states associated with detection or matching of one or more predetermined signals on distinct conduction paths between elements of the control system and related methods

The invention claimed is: 1. A control and configuration system for a safety critical device comprising: a control panel configured to receive user inputs used to configure or control a device, said control panel comprising a plurality of user operated controls, one or more equipment operational status displays; a transmitter communicatively coupled with the control panel, the transmitter comprising a first logic unit including a first plurality of logic elements configured to selectively implement a first state machine, the first state machine comprising a first plurality of identifiable states, wherein said first plurality of identifiable states comprises a first power-up safe state, a first ready-to-operate state, and a first operate state; a receiver system comprising a second logic unit including a second plurality of logic elements configured to selectively implement a second state machine, the second state machine comprising a second plurality of identifiable states, wherein said second plurality of identifiable states comprises a second power-up safe state, a lock-out state, a second ready-to-operate state, and a second operate state, wherein said receiver system is communicatively coupled with said device; and a control bus containing a plurality of wires, the control bus electrically coupling the transmitter and the receiver; wherein, the transmitter is configured to transmit to the receiver, via the control bus one set of a plurality of discrete signal sets that are each respectively associated with each of said first plurality of identifiable states that the first state machine has selected or instantiated from said plurality of first identifiable states based on input from said user operated controls; wherein said plurality of discrete signal sets respectively comprises a first, second, and third discrete signal sets, wherein said first discrete signal set comprises a first signal pattern associated with said first power-up safe state, said second discrete signal set comprises a second signal pattern associated with said first ready to operate state, and said third discrete signal set is associated with said operate state, wherein said first plurality of logic elements are configured to generate said first and second discrete signal sets as constant logic signals, said first plurality of logic elements are configured to generate said third discrete signal set as a time varying logic signal; wherein said receiver is communicatively coupled with the device to configure and operate said device based on inputs received from said transmitter comprising said plurality of discrete signal sets; wherein said second logic unit is configured to select one of said second plurality of identifiable states based on said first, second or third discrete signal sets; wherein said receiver comprises a receiver clock, said receiver clock selectively configures or operates said device based on said second plurality of identifiable states, wherein said receiver monitors said inputs received from said transmitter and starts said receiver clock upon transition between said ready-to-operate state and said operate state in order to measure said time varying logic signal associated with said third discrete signal set; wherein said lock-out state is selected by said second logic unit based on an internal error detected by the receiver, input conditions to the receiver equal an unrecognized state not matching one of said second identifiable states, or said discrete signal sets received by the transmitter via the control bus that do not transition between said second power-up safe state, said second ready to operate state, and said second operate state based on transition criteria stored or accessed by said receiver. 2. The system of claim 1 wherein the first state machine configures said transmitter to invert each logic value in said second discrete signal sets to generate said third discrete signal sets through the control bus. 3. The system of claim 1 wherein the transmitter is configured to operate said first state machine by transmitting said first, second, and third discrete signal sets with predetermined values through the control bus to the receiver to operate the second state machine in order to transition between states of the second state machine. 4. The system of claim 1 wherein the transmitter is configured to operate the first state machine by transmitting said first, second, and third discrete signal sets through the control bus which must be received by the receiver within a specified timeframe stored in said receiver in order to transition between the second plurality of identifiable states of the second state machine. 5. The system of claim 1 , said transmitter is further configured to transmit a feedback control signal to the control panel through the transmitter to enable the receiver via the control panel to indicate a fault condition using one of said equipment operational status displays. 6. The system of claim 1 configured to control a weapon system. 7. The system of claim 1 , wherein said device comprises a laser. 8. A method of controlling a control and configuration system for a safety critical device, the method comprising: operating a user control panel operable for controlling and configuring a safety critical device and sending one or more user inputs from the user control panel to a transmitter comprising a first plurality of logic elements that selectively implements a first state machine, the first state machine comprising a first plurality of identifiable states, wherein said first plurality of identifiable states comprises a first power-up safe state, a first ready-to-operate state, and a first operate state, wherein each of said first plurality of identifiable states are associated with one of a first plurality of discrete signal sets; identifying and correlating said user inputs using the first state machine with one of said first plurality of identifiable states to determine a current first identifiable state correlated with said user inputs; communicating one of said first plurality of discrete signals set associated with the current first identifiable state to a receiver comprising a second plurality of logic elements configured to selectively implement a second state machine, the second state machine comprising a second plurality of identifiable states each associated with a second plurality of discrete signal sets, wherein said second plurality of identifiable states comprises a second power-up safe state, a lock-out state, a second ready-to-operate state, and a second operate state, wherein said receiver system is communicatively coupled with said safety critical device; and determining and correlating said first discrete signals set with one of said second plurality of second discrete signal sets associated to determine a second current state; wherein said receiver comprises a receiver clock, said receiver clock selectively configures or operates said safety critical device based on said current state, wherein said receiver monitors inputs received from said transmitter and starts said receiver clock upon transition between said ready-to-operate state and said operate state in order to measure a time varying logic signal associated with a time varying discrete signal state associated with said operate state; wherein said lock-out state is selected by said second plurality of logic elements based on an internal error detected by the receiver, input conditions to the receiver equal an unrecognized state not matching one of said second identifiable states, or said discrete signal sets received by the transmitter that do not transition between said second power-up safe state, said second ready to operate state, and said second ope