Heterogeneous method for energy efficient distribution of on-chip power supplies and power network on-chip system for scalable power delivery

What is claimed is: 1. A power network on-chip (PNoC) for an integrated circuit comprising: one or more voltage clusters, each voltage cluster comprising: a plurality of locally powered loads; a plurality of power routers disposed in a mesh circuit topology as a mesh of power routers, said mesh of power routers configured to receive power from one or more power converters, each of said power routers electrically coupled to and configured to power a locally powered load, adjacent power routers of said plurality of power routers electrically coupled to each other via a switch of a plurality of switches; and at least one programmable unit communicatively coupled to said plurality of switches, said programmable unit adapted to manage power delivery to said locally powered loads of said one or more voltage clusters by configuring a switch position of at least a subset of switches of said plurality of switches based on sensed voltages and currents within said one or more voltage clusters. 2. The PNoC of claim 1 , wherein said programmable unit is configured to apply a new set of said switch positions substantially in real-time on a time-slot basis. 3. The PNoC of claim 1 , wherein said at least one programmable unit comprises a microcontroller disposed on said integrated circuit. 4. The PNoC of claim 1 , wherein one or more power routers of said plurality of power routers is a complex power delivery system comprising one or more sensors, one or more dynamically adaptable power supplies, one or more switches and a microcontroller configured to control said one or more dynamically adaptable power supplies and said one or more switches in response to measurements based on said one or more sensors. 5. A heterogeneous power distribution system for an integrated circuit comprising: a power network-on-chip (PNoC) configured to receive electrical power from one or more off-chip power converters, said power network-on-chip comprising a mesh of power routers electrically coupled to and configured to power a plurality of on-chip loads, said mesh of power routers including: a plurality of integrated simple power routers; and a plurality of integrated complex power routers, each complex power router of said plurality of complex power routers comprising a microcontroller communicatively coupled to one or more switches and one or more sensors of said complex power router, said microcontroller configured to run a process algorithm that dynamically routes and controls power according to a power delivery policy by controlling said one or more switches based on information received from said one or more sensors. 6. The power distribution system of claim 5 , wherein each power domain of a plurality of power domains is controlled by a power router of said mesh of power routers. 7. The power distribution system of claim 5 , wherein one or more of said plurality of integrated simple power routers comprises a linear voltage regulator. 8. The power distribution system of claim 7 , wherein at least one complex power router controls a plurality of linear low dropout regulators within a common power domain. 9. The power distribution system of claim 5 , wherein said power network-on-chip receives a converted electrical power from a plurality of off-chip switching power converters and delivers a regulated electrical power to a plurality of on-chip voltage clusters. 10. The power distribution system of claim 5 , wherein said power network-on-chip comprises one or more real-time dynamic voltage scaling circuits. 11. The power distribution system of claim 5 , wherein said power network-on-chip comprises one or more real-time dynamic frequency scaling circuits. 12. The power distribution system of claim 5 , wherein said power network-on-chip comprises one or more real-time adaptable energy allocation circuits. 13. The power distribution system of claim 5 , wherein said power network-on-chip comprises one or more adaptive RC compensation networks. 14. The power distribution system of claim 13 , wherein said RC compensation network comprises a capacitive block electrically coupled to two series resistive blocks, said capacitive block and said two series resistive blocks digitally controlled and digitally configured to stabilize a linear regulator under a wide range of process variations. 15. The power distribution system of claim 5 , wherein said power network-on-chip comprises one or more adaptive current boost networks. 16. The power distribution system of claim 15 , wherein at least one of said one or more adaptive current boost networks is electrically coupled to and controls a current through a differential pair of a linear regulator, and wherein when a high slew rate transition at an output of said linear regulator occurs, a boost mode is activated, raising a tail current of said differential pair, or alternatively, during a regular mode causing substantially no additional current flow into said differential pair, enhancing a power efficiency of said linear regulator. 17. The power distribution system of claim 5 , wherein said power network-on-chip controls an on-chip quality of power factor. 18. A method to determine a near optimal distribution of power supply resources in a heterogeneous power delivery system comprising the steps of: providing an electronic system programmed to distribute power supply resources in said heterogeneous power delivery system; accepting by computer process a set of voltage domain information including a number N of on-chip voltage domains and a voltage V and current load I for each of said on-chip voltage domains and a maximum number N S,MAX of off-chip switching mode power supplies; calculating by a computer process that is more computationally efficient than an exhaustive optimal computation by use of at least a selected one of: a binary power supply clustering process and a linear power supply clustering process, based on said set of voltage domain information and said maximum number N S,MAX of off-chip switching mode power supplies, a near optimal set of voltage clusters comprising a number and distribution of linear low dropout regulators associated with each cluster, said linear low dropout regulators configured to power each of said on-chip voltage domains; and configuring said electronic system to said near optimal distribution of power supply resources based on said near optimal set of voltage clusters. 19. The method of claim 18 , further comprising at each step of said binary power supply clustering process a step of identifying a specific voltage cluster having a widest voltage range and distributing one or more of said linear low dropout regulators into two separate clusters. 20. The method of claim 18 , wherein said linear power supply clustering process linearly distributes a plurality of linear low dropout regulators within said voltage clusters.