Application of the extrema distortion method to optimize control signals

What is claimed is: 1. A system for controlling a signaling pathway in a subject of interest, comprising: a sensor configured to observe a signal in the subject of interest, and configured to provide an electrical representation of said signal for further manipulation; a module configured to accept as input said electrical representation of said signal for further manipulation; a module configured to apply the Extrema Distortion Algorithm to said electrical representation of said signal, and configured to generate a synthetic control signal; a module configured to provide said synthetic control signal as an output; and a signal application module configured to receive said synthetic control signal and configured to apply said synthetic control signal to the subject of interest, wherein said module configured to apply the Extrema Distortion Algorithm is a general purpose programmable computer which when operating under control of instructions recorded on a non-volatile medium is configured to perform the steps of said Extrema Distortion Algorithm, and said Extrema Distortion Algorithm includes instructions recorded on said non-volatile medium that are configured to direct said general purpose computer to: (a) Select a randomly generated starting seed that successfully causes a state transition, (b) Find the extrema of the starting seed and measure the time interval between them, (c) Multiply each of the time intervals by a randomly generated number (e.g. with a Gaussian distribution), (d) Rescale the time of the synthetic stimulus to match the duration of the original stimulus, (e) Add to each peak a randomly generated number (e.g. with a Gaussian distribution), (f) Linearly transform all the data points between the extrema with the new extrema endpoints, (g) Test the distorted stimulus in the system, checking to see if it achieves pre-specified constraints, (h) Calculate the performance metric (e.g. L 2 -norm) of each of the neighboring stimuli, (i) Repeat steps (c)-(h) N times to produce N neighboring solutions based on the starting seed, (j) Choose the stimulus from among the neighboring solutions and the starting seed with the best performance, (k) Repeat steps (b)-(j) for a predetermined number of times M each iteration using the best stimuli found from the previous iteration as the new starting seed in step (b), and (l) After M iterations, output the stimulus with the best performance metric as the optimal stimulus. 2. The system for controlling a signaling pathway in a subject of interest of claim 1 , wherein said sensor configured to observe a signal is configured to provide said electrical representation in the form of an analog signal having an amplitude and a phase. 3. The system for controlling a signaling pathway in a subject of interest of claim 1 , wherein said sensor configured to observe a signal is configured to provide said electrical representation in the form of a plurality of discrete time based signals, each discrete signal having an amplitude and an identifier indicating the position of the signal in a time sequence. 4. The system for controlling a signaling pathway in a subject of interest of claim 1 , wherein said module configured to accept as input said electrical representation is a data acquisition module. 5. The system for controlling a signaling pathway in a subject of interest of claim 1 , wherein said module configured to provide said synthetic control signal as an output is a data acquisition module having a data output port.