Use of the unused duration injection units in an array to reduce oscillations during impedance injection for corrections of problems

What is claimed is: 1. A method of operating an impedance injection module (IIM) comprising a plurality of transformer-less flexible alternating current transmission system (TL-FACTS) based impedance injection units (IIUs), the method comprising: controlling, by a control module of the IIM, the plurality of TL-FACTS based IIUs of the IIM forming multiple connection configurations in sequence, each connection configuration comprising multiple TL-FACTS based IIUs in series, parallel or combination thereof, wherein the IIM is coupled to a high-voltage (HV) transmission line; generating, by the TL-FACTS based IIUs through the multiple connection configurations of the TL-FACTS based IIUs in sequence, a plurality of synchronized rectangular impedance injection waveforms that when combined and injected into the HV transmission line, produce a pseudo-sinusoidal impedance waveform; sensing, by a plurality of sensors coupled to the HV transmission line, presence of a disturbance on the HV transmission line; and generating and injecting into the HV transmission line one or more short duration pulses by at least one TL-FACTS based IIU that is not being utilized during that period of generating the synchronized rectangular impedance injection waveforms; wherein the one or more short duration pulses injected into the HV transmission line correct the disturbance on the HV transmission line. 2. The method of claim 1 , wherein the pseudo-sinusoidal impedance waveform reduces generation of oscillations on the HV transmission line, as compared to injection of a single rectangular impedance injection waveform into the HV transmission line. 3. The method of claim 1 , wherein the plurality of synchronized rectangular impedance injection waveforms are synchronized to generate a sequence of rectangular waveforms that when combined and injected into the HV transmission line, produces the pseudo-sinusoidal impedance waveform. 4. The method of claim 1 , further comprising: synchronizing, through a communication unit, the controlling the plurality of TL-FACTS based IIUs of the TIM and the generating the plurality of synchronized rectangular impedance injection waveforms with one or more clocks that are local to the control module and the plurality of TL-FACTS based IIUs. 5. The method of claim 1 , further comprising: synchronizing one or more clocks that are local to the control module and the plurality of TL-FACTS based IIUs, to a Global Positioning System (GPS) clock. 6. The method of claim 1 , further comprising: generating and injecting one or more additional pulses of shorter duration than the sequence, into the HV transmission line, by the control module through one or more of the plurality of TL-FACTS based IIUs not otherwise being used during that period in the multiple connection configurations of the TL-FACTS based IIUs in the sequence that produces the pseudo-sinusoidal impedance waveform, in response to the sensing the presence of the disturbance. 7. The method of claim 1 , further comprising: generating and injecting one or more additional pulses to the HV transmission line, by the control module through the plurality of TL-FACTS based IIUs during their unused periods, to respond to and correct the disturbance on HV transmission line. 8. An impedance injection system comprising one or more impedance injection modules (IIMs), the impedance injection system comprising: a plurality of transformer-less flexible alternating current transmission system (TL-FACTS) based impedance injection units (IIUs) of an IIM; and a control module to: direct the plurality of TL-FACTS based IIUs of the IIM to form connection configurations in sequence, with each connection configuration comprising multiple TL-FACTS based IIUs connected in series, parallel or combination thereof, wherein the IIM is coupled to a high-voltage (HV) transmission line; generate, through the connection configurations of TL-FACTS based IIUs in the sequence, synchronized rectangular impedance injection waveforms to combine and inject into the HV transmission line, to produce a pseudo-sinusoidal impedance waveform on the HV transmission line; and generate, through the connection configurations of TL-FACTS based IIUs, during an unused period in the sequence, one or more short duration pulses to be injected into the HV transmission line to correct a sensed disturbance on the HV transmission line. 9. The impedance injection system of claim 8 , wherein the control module further to smooth the synchronized rectangular impedance injection waveforms to produce the pseudo-sinusoidal impedance waveform to reduce generation of oscillations on the HV transmission line in comparison to injection of a single rectangular impedance injection waveform into the HV transmission line. 10. The impedance injection system of claim 8 , further comprising the control module to synchronize the rectangular impedance injection waveforms to the sequence of connection configurations of the TL-FACTS based IIUs. 11. The impedance injection system of claim 8 , further comprising: a communication unit to synchronize the connection configurations and the rectangular impedance injection waveforms with one or more clocks that are local to the control module and the plurality of TL-FACTS based IIUs. 12. The impedance injection system of claim 8 , further comprising: a communication unit to synchronize one or more clocks that are local to the control module and the plurality of TL-FACTS based IIUs, to a Global Positioning System (GPS) clock. 13. The impedance injection system of claim 8 , further comprising: one or more sensors, for connection to the high-voltage transmission line; and the control module to generate and inject, through one or more TL-FACTS based IIUs that are not at that time being used in the connection configurations in the sequence, one or more additional pulses of shorter duration than the sequence, into the HV transmission line in response to sensing a disturbance on the HV transmission line. 14. The impedance injection system of claim 8 , further comprising: the control module to generate and inject, through the plurality of TL-FACTS based IIUs, one or more additional pulses into the HV transmission line, to respond to and correct a disturbance on the HV transmission line. 15. A tangible, non-transitory, computer-readable media having instructions thereupon which, when executed by a processor, cause the processor to: direct a plurality of transformer-less flexible alternating current transmission system (TL-FACTS) based impedance injection units (IIUs) of an impedance injection module (IIM) to form connection configurations in sequence, with each connection configuration comprising multiple IIUs connected in series, parallel or combination thereof, wherein the IIM is coupled to a high-voltage (HV) transmission line; generate, through the connection configurations of TL-FACTS based IIUs in the sequence, synchronized rectangular impedance injection waveforms to combine and inject into the HV transmission line, to produce a pseudo-sinusoidal impedance waveform on the HV transmission line; and generate, through the connection configurations of TL-FACTS based IIUs, during an unused period in the sequence, one or more short duration pulses to be injected into the HV transmission line to correct a sensed disturbance on the HV transmission line. 16. The tangible, non-transitory, computer-readable media of claim 15 , wherein the instructions further cause the processor to: synchronize the rectangular impedance injection waveforms to the sequence of connectio