System and method for control of distributed energy resources for distribution grid voltage stability

What is claimed is: 1 . A smart inverter used in a photovoltaic (PV) generation system, the smart inverter comprising: a PV control logic device selected from the group consisting of a volt-VAR (VV) control logic device, a volt-WATT (VW) control logic device, and a VV/VW control logic device; and at least one low pass filter coupled to and in communication with the at least one PV control logic device. 2 . The smart inverter of claim 1 wherein the at least one low pass filter comprises two low pass filters, one low pass filter coupled to one logic controller and another low pass filter coupled to another logic controller. 3 . The smart inverter of claim 1 wherein the PV control logic device comprises a first VV/VW control logic device coupled to a grid both the first VV/VW control logic device and the second VV/VW control logic device receiving maximum available active power from a solar array and voltage v and computing reactive set points. 4 . The smart inverter of claim 3 wherein the at least one low pass filter comprises a first low pass filter coupled to the first VV/VW control logic device and producing active power injections into the grid and a second low pass filter coupled to the second VV/VW control logic device and producing reactive power injections into the grid. 5 . A distributed energy resource system, the system comprising: a grid having voltage v, one or more unstable devices coupled to at least the grid and adapted to inject active power p and reactive power q into the grid, and one or more controllable devices coupled to at least the grid, the controllable devices adapted to inject active power p and reactive power q into the grid, where voltage v is measured, and active power p and reactive power q are adjusted by an adaptive control signal u. 6 . The system of claim 5 wherein at least one of the one or more controllable devices comprises: a smart inverter device adapted to inject active power p and reactive power q into the grid; at least one adaptive controller coupled to the grid and the smart inverter device, where voltage v is measured, and active power p and reactive power q are adjusted by an adaptive control signal u. 7 . The system of claim 6 wherein the smart inverter device comprises: a PV control logic device; and at least one low pass filter coupled to and in communication with at least the PV control logic device. 8 . The smart inverter device of claim 7 wherein the PV control logic device comprises a first VV/VW control logic device coupled to the grid and receiving a maximum available amount of active power from a solar array and voltage v and computing active set points, and a second VV/VW control logic device coupled to the grid and receiving maximum available active power from a solar array and voltage v and computing reactive set points. 9 . The smart inverter device of claim 8 wherein at least one low pass filter comprises a first low pass filter coupled to the first VV/VW control logic device and producing active power injections into the grid and a second low pass filter coupled to the second VV/VW control logic device and producing reactive power injections into the grid. 10 . A method for controlling a distributed energy resource system, the method comprising: receiving a maximum available amount of active power from a solar array and voltage v from a grid and computing active set points forming computed active set points; producing active power injection values using the computed active set points, inputting the active power injection values into the grid; producing reactive power injection values; and inputting the reactive power injection values into the grid. 11 . The method of claim 10 further comprising computing reactive set points used to produce the reactive power injection values. 12 . The method of claim 11 further comprising receiving a maximum available amount of reactive power from a solar array and voltage v from the grid and computing the reactive set points. 13 . A smart inverter used in a photovoltaic (PV) generation system, the smart inverter comprising: a PV control logic device comprising a first VV/VW control logic device coupled to a grid-and a second VV/VW control logic device coupled to the grid, where both the first VV/VW control logic device and the second VV/VW control logic device receiving maximum available active power from a solar array and voltage v and computing reactive set points; and at least one low pass filter coupled to and in communication with the at least one PV control logic device. 14 . The smart inverter of claim 13 wherein the at least one low pass filter comprises two low pass filters, one low pass filter coupled to one logic controller and another low pass filter coupled to another logic controller. 15 . The smart inverter of claim 13 wherein the at least one low pass filter comprises a first low pass filter coupled to the first VV/VW control logic device and producing active power injections into the grid and a second low pass filter coupled to the second VV/VW control logic device and producing reactive power injections into the grid. 16 . A method for controlling a distributed energy resource system, the method comprising: producing active power injection values; inputting the active power injection values into a grid; receiving a maximum available amount of reactive power from a solar array and voltage v from the grid and computing the reactive set points; producing reactive power injection values using the reactive set points; and inputting the reactive power injection values into the grid. 17 . The method of claim 16 further comprising receiving a maximum available amount of active power from a solar array and voltage v from the grid and computing active set points. 18 . The method of claim 17 further providing the active power injection values using the active set points.