Apparatus for efficient measurement of tone frequency, amplitude, and phase

What is claimed is: 1. An apparatus for efficient tone frequency, amplitude and phase measurement, comprising: a signal conditioner having an input and an output; an analog-to-digital converter having an input and an output; a parser having an input and an output; a Fourier Transformer having an input and an output; a selector having an input and an output; a first processor having a signal input, an output, and a coefficient input, wherein, an external analog signal to be measured x(t) is input into said input of said signal conditioner and conditioned therein; the conditioned signal output of said signal conditioner is connected to the input of said analog-to-digital converter whereupon it is sampled; the sampled signal output of said analog-to-digital converter is connected to the input of said parser, wherein said parser parses the digital output of said analog-to-digital converter x[n] into m data segments of length N, wherein the m th said segment is represented as x m [n]; the x m [n]data segments output of said parser are connected to the input of said Fourier Transformer, wherein said Fourier Transformer performs an N-point Discrete Fourier Transform on x m [n], resulting in X m [k], wherein k is the k th frequency bin along a discrete frequency independent variable, and X m [k] is the Discrete Fourier Transform of any said data segment; the X m [k]output of said Fourier Transformer is connected to the input of said first processor and to the input of said selector; and wherein the output of said selector is connected to the coefficient input of said first processor, wherein said selector selects a set of frequency indices for which frequency measurements are to be performed; and wherein said first processor performs a first step of processing a ratio R m [k] represented by R m [k ]=( X m [k− 1]− X m [k+ 1])/( X m [k− 1]+ X m [k+ 1]−2 X m [k ]) performs a second step of processing r m [k] represented by r m [k]=Re{R m [k ]}; and performs a third step of processing a frequency measurement w m [k] represented by w m [k ]=mod { k−r m [k],N}− 1; a second processor having a tone frequency input, a data segment input an amplitude output, and a phase output; wherein said tone frequency input is connected to the output of said first processor; and said data segment input is connected to said output of said parser; wherein said second processor further comprises: a plurality of value registers having an input and an output, said input being connected to said data segment input into which each of said data segment sequences are sequentially input; a first plurality of cosine registers having a cosine weighting, a tone frequency input connected to said output of said first processor, and an output; a first plurality of sine registers having a sine weighting, a tone frequency input connected to said output of said first processor, and an output; a first plurality of multipliers each having an input connected to the output of a corresponding cosine register and to the output of a corresponding value register commencing with a second said value register, for cosine weighting a corresponding data segment; a second plurality of multipliers each having an input connected to the output of a corresponding sine register and to the output of a corresponding value register commencing with a second said value register, for sine weighting a corresponding data segment; a first summer having an in-phase output and having as inputs the outputs of all said first plurality of multipliers and the output of a first said plurality of value registers, for summing said cosine weighted data segments; a second summer having a quadrature phase output and having as inputs the outputs of all said second plurality of multipliers, for summing said sine weighted data segments; wherein said first and said second summer outputs are processed according to 2/ N √{square root over (( i 1 2 )}+ q 1 2 ) so as to provide an initial amplitude measurement at said amplitude output; and wherein said first and said second summer outputs are processed according to arg{i 1 −j*q 1 } i 1 is an initial in-phase component of phase measurement; q 1 is an initial quadrature phase component of phase measurement; N is the length of said data segments; and j is √{square root over (−1)} so as to provide an initial phase measurement at said phase output. 2. The apparatus of claim 1 , wherein said Fourier Transformer performs a Fast Fourier Transform on x m [n], resulting in X m [k], wherein k is the k th frequency bin along a discrete frequency independent variable, and X m [k] is the Fast Fourier Transform of any said data segment. 3. The apparatus of claim 1 , wherein said selector performs a threshold and detect function. 4. The apparatus of claim 1 , further comprising a third processor, wherein said third processor further comprises a second plurality of cosine registers each having a cosine weighting, a tone frequency input connected to said output of said first processor, a phase input connected to said phase output of said second processor, and an output which produces a cosine weighted value corresponding to said input tone and input phase; a second plurality of sine registers each having a sine weighting, a tone frequency input connected to said output of said first processor, a phase input connected to said phase output of said second processor, and an output which produces a sine weighted value corresponding to said input tone and input phase; a first summer with an input being connected to and summing all said outputs of all said cosine registers, and an output; a second summer with an input being connected to and summing all said outputs of all said sine registers, and an output; a first scalar having an input connected to the output of said first summer for scaling the output of said first summer, an input connected to said amplitude output of said second processor, and an output; a second scalar having an input connected to the output of said second summer for scaling the output of said second summer, an input connected to said amplitude output of said second processor, and an output; a third summer having an input connected to said output of said first scalar; an input connected to said in-phase output of said second processor for summing said scaled output of said first scalar and said in-phase output of said second processor, and an in-phase output; a fourth summer having an input connected to said output of said second scalar, an input connected to said quadrature phase output of said second processor for summing said scaled output of said second scalar and said quadrature-phase output of said second processor, and a quadrature phase output; wherein said third and said fourth summer outputs are processed according to ( i 2 2 + q 2 2 ) 2 N so as to provide a refined amplitude measurement at said amplitude output; and wherein said third and said fourth summer outputs are processed according to arg{i 2 −j*q 2 } where i 2 is a refined in-phase component of phase measurement; q 2 is a refined quadrature phase component of phase measurement; N is the length of said data segments; j is √{squa