Intelligent electronic device and method thereof

What is claimed is: 1. An intelligent electronic device comprising: a metering module configured to receive at least one alternating current (AC) voltage waveform and/or AC current waveform from an AC electrical service, the at least one AC voltage waveform and/or AC current waveform including a plurality of cycles occurring sequentially, each cycle of the plurality of cycles including two half-cycles, the metering module further configured to obtain waveform samples from the at least one AC voltage waveform and/or AC current waveform; a memory module configured to store the waveform samples obtained by the metering module; and a processing module configured to process the waveform samples stored in the memory module at each half-cycle; wherein the processing module performs pipeline processing for each half-cycle to evaluate the stored waveform samples corresponding in operating times based on a trigger condition occurring a predefined number of half-cycles before an evaluation point in the at least one AC voltage waveform and/or AC current waveform; wherein the processing module defers checking for the trigger condition until a predefined number of samples to be evaluated has been obtained by the metering module and stored in the memory module; and wherein the processing module captures a block of waveform samples based on the trigger condition and stores the captured block of waveform samples in the memory module. 2. The intelligent electronic device of claim 1 , wherein the captured block of waveform samples spans from a begin capture time to an end capture time in the at least one AC voltage and/or AC current waveform, the begin capture time and the end capture time determined by the processing module based on the trigger condition. 3. The intelligent electronic device of claim 2 , wherein the begin capture time and the end capture time are further based on a reference signal waveform including a plurality of cycles occurring sequentially, each cycle of the plurality of cycles in the reference signal waveform including two half-cycles, wherein the begin capture time occurs at a first half-cycle of the reference signal waveform and the end capture time occurs at a second half-cycle of the reference signal. 4. The intelligent electronic device of claim 3 , wherein the reference signal includes a frequency of 60 Hz. 5. The intelligent electronic device of claim 1 , wherein the memory module is configured to store the predefined number of waveform samples to be evaluated regardless of a frequency of the at least one AC voltage waveform and/or AC current waveform. 6. The intelligent electronic device of claim 1 , wherein the at least one AC voltage waveform and/or AC current waveform having frequencies between a minimum frequency of 45 Hz and a maximum frequency of 65 Hz. 7. The intelligent electronic device of claim 1 , wherein the processing module is configured to calculate an RMS value for each half-cycle of the at least one AC voltage waveform and/or AC current waveform. 8. The intelligent electronic device of claim 7 , wherein the memory module comprises a FIFO buffer, and wherein the RMS values for each half-cycle are stored in the FIFO buffer. 9. The intelligent electronic device of claim 1 , further comprising an input module configured to enable a user to select a predefined number of half-cycles from the trigger condition to the evaluation point, a predefined number of waveform samples to be obtained per second, and a predefined number of pre-trigger half-cycles to be included in the captured block of waveform samples. 10. The intelligent electronic device of claim 9 , wherein the user interface includes at least one of pushbuttons and/or a touch screen. 11. The intelligent electronic device of claim 1 , wherein the at least one AC voltage waveform and/or AC current waveform comprises three AC voltage waveforms and three AC current waveforms. 12. The intelligent electronic device of claim 1 , wherein the processing module is further configured to link power quality event cycles to an associated captured block and postpone evaluation of the power quality event until the captured block is passed. 13. The intelligent electronic device of claim 1 , wherein the memory module includes at least a first buffer and a second buffer and the waveform samples from the at least one AC voltage waveform and/or AC current waveform are stored in the at least first buffer and the captured block of waveform samples are stored in the second buffer. 14. The intelligent electronic device of claim 1 , further comprising a communication module configured to transmit the captured block to a remote terminal after the trigger condition is detected. 15. The intelligent electronic device of claim 1 , wherein the intelligent electronic device is at least one of a digital electrical power and energy meter, a Programmable Logic Controller (PLC), a Remote Terminal Unit, a protective relay, and/or a fault recorder. 16. An intelligent electronic device comprising: a metering module coupled to an alternating current (AC) electrical distribution system for obtaining waveform samples from an AC waveform to be evaluated, the AC waveform including a plurality of cycle occurring sequentially, each cycle of the plurality of cycles including two half-cycles; a buffer module configured to store the waveform samples obtained by the metering module; and a processing module configured to process the waveform samples at each half-cycle; wherein the processing module is configured to evaluate the stored waveform samples corresponding in operating times based on a trigger condition occurring a predefined number of half-cycles before an evaluation point in the AC waveform. 17. The intelligent electronic device of claim 16 , wherein the processing module is configured to defer checking for the trigger condition until a predefined number of waveform samples to be evaluated has been obtained by the metering module and stored in the buffer module. 18. The intelligent electronic device of claim 16 , wherein the buffer module is configured to store a predefined number of waveform samples regardless of the frequency of the AC waveform. 19. The intelligent electronic device of claim 16 , wherein the processing module is configured to calculate an RMS value for each half-cycle of the AC waveform. 20. The intelligent electronic device of claim 19 , wherein the buffer module comprises a FIFO buffer, and wherein the RMS values for each half-cycle are stored in the FIFO buffer. 21. The intelligent electronic device of claim 16 , wherein the processing module captures a block of waveform samples based on the trigger condition and stores the captured block of waveform samples in a second buffer module. 22. The intelligent electronic device of claim 21 , the captured block of waveform samples spans from a begin capture time to an end capture time in the at least one AC voltage and/or AC current waveform, the begin capture time and the end capture time determined by the processing module based on the trigger condition. 23. The intelligent electronic device of claim 22 , wherein the begin capture time and the end capture time are further based on a reference signal waveform including a plurality of cycles occurring sequentially, each cycle of the plurality of cycles in the reference signal waveform including two half-cycles, wherein the begin capture time occurs at a first half-cycle of the reference signal waveform an