Estimation of signal parameters via rotational invariance techniques

Estimation of signal parameters via rotational invariant techniques (ESPRIT), is a technique to determine the parameters of a mixture of sinusoids in background noise. This technique was first proposed for frequency estimation.^[1] However, with the introduction of phased-array systems in everyday technology, it is also used for angle of arrival estimations.^[2]

One-dimensional ESPRIT[edit]

At instance ${\textstyle t}$ , the ${\textstyle M}$ (complex -valued) output signals (measurements) ${\textstyle y_{m}[t]}$ , ${\textstyle m=1,\ldots ,M}$ , of the system are related to the ${\textstyle K}$ (complex -valued) input signals ${\textstyle x_{k}[t]}$ , ${\textstyle k=1,\ldots ,K}$ , as $y_{m}[t]=\sum _{k=1}^{K}a_{m,k}x_{k}[t]+n_{m}[t],$ where ${\textstyle n_{m}[t]}$ denotes the noise added by the system. The one-dimensional form of ESPRIT can be applied if the weights have the form ${\textstyle a_{m,k}=e^{-j(m-1)\omega _{k}}}$ , whose phases are integer multiples of some radial frequency $\omega _{k}$ . This frequency only depends on the index of the system's input, i.e., ${\textstyle k}$ . The goal of ESPRIT is to estimate $\omega _{k}$ 's, given the outputs ${\textstyle y_{m}[t]}$ and the number of input signals, ${\textstyle K}$ . Since the radial frequencies are the actual objectives, ${\textstyle a_{m,k}}$ is denoted as ${\textstyle a_{m}(\omega _{k})}$ .

Collating the weights ${\textstyle a_{m}(\omega _{k})}$ as $\mathbf {a} (\omega _{k})=[\,1\,\ e^{-j\omega _{k}}\,\ e^{-j2\omega _{k}}\,\ ...\,\ e^{-j(M-1)\omega _{k}}\,]^{\top }$ and the ${\textstyle M}$ output signals at instance ${\textstyle t}$ as $\mathbf {y} [t]=[\,y_{1}[t]\,\ y_{2}[t]\,\ ...\,\ y_{M}[t]\,]^{\top }$ , $\mathbf {y} [t]=\sum _{k=1}^{K}\mathbf {a} (\omega _{k})x_{k}[t]+\mathbf {n} [t],$ where $\mathbf {n} [t]=[\,n_{1}[t]\,\ n_{2}[t]\,\ ...\,\ n_{M}[t]\,]^{\top }$ . Further, when the weight vectors $\mathbf {a} (\omega _{1}),\ \mathbf {a} (\omega _{2}),\ ...,\ \mathbf {a} (\omega _{K})$ are put into a Vandermonde matrix $\mathbf {A} =[\,\mathbf {a} (\omega _{1})\,\ \mathbf {a} (\omega _{2})\,\ ...\,\ \mathbf {a} (\omega _{K})\,]$ , and the $K$ inputs at instance ${\textstyle t}$ into a vector $\mathbf {x} [t]=[\,x_{1}[t]\,\ ...\,\ x_{k}[t]\,]^{\top }$ , we can write $\mathbf {y} [t]=\mathbf {A} \,\mathbf {x} [t]+\mathbf {n} [t].$ With several measurements at instances ${\textstyle t=1,2,\dots ,T}$ and the notations ${\textstyle \mathbf {Y} =[\,\mathbf {y} [1]\,\ \mathbf {y} [2]\,\ \dots \,\ \mathbf {y} [T]\,]}$ , ${\textstyle \mathbf {X} =[\,\mathbf {x} [1]\,\ \mathbf {x} [2]\,\ \dots \,\ \mathbf {x} [T]\,]}$ and ${\textstyle \mathbf {N} =[\,\mathbf {n} [1]\,\ \mathbf {n} [2]\,\ \dots \,\ \mathbf {n} [T]\,]}$ , the model equation becomes $\mathbf {Y} =\mathbf {A} \mathbf {X} +\mathbf {N} .$

Dividing into virtual sub-arrays[edit]

The weight vector ${\textstyle \mathbf {a} (\omega _{k})}$ has the property that adjacent entries are related. $[\mathbf {a} (\omega _{k})]_{m+1}=e^{-j\omega _{k}}[\mathbf {a} (\omega _{k})]_{m}$ For the whole vector $\mathbf {a} (\omega _{k})$ , the equation introduces two selection matrices $\mathbf {J} _{1}$ and $\mathbf {J} _{2}$ : $\mathbf {J} _{1}=[\mathbf {I} _{M-1}$ and $\mathbf {J} _{2}=[\mathbf {0} \quad \mathbf {I} _{M-1}]$ . Here, $\mathbf {I} _{M-1}$ is an identity matrix of size ${\textstyle (M-1)}$ and $\mathbf {0}$ is a vector of zero.

The vectors $\mathbf {J} _{1}\mathbf {a} (\omega _{k})$ $[\mathbf {J} _{2}\mathbf {a} (\omega _{k})]$ contains all elements of $\mathbf {a} (\omega _{k})$ except the last [first] one. Thus, $\mathbf {J} _{2}\mathbf {a} (\omega _{k})=e^{-j\omega _{k}}\mathbf {J} _{1}\mathbf {a} (\omega _{k})$ and $\mathbf {J} _{2}\mathbf {A} =\mathbf {J} _{1}\mathbf {A} \mathbf {H} ,\quad {\text{where}}\quad {\mathbf {H} }:={\begin{bmatrix}e^{-j\omega _{1}}&\\&e^{-j\omega _{2}}\\&&\ddots \\&&&e^{-j\omega _{K}}\end{bmatrix}}.$ The above relation is the first major observation required for ESPRIT. The second major observation concerns the signal subspace that can be computed from the output signals.

Signal subspace[edit]

The singular value decomposition (SVD) of ${\textstyle \mathbf {Y} }$ is given as $\mathbf {Y} =\mathbf {U} \mathbf {\Sigma } \mathbf {V} ^{\dagger }$ where ${\textstyle \mathbf {U} \in \mathbb {C} ^{M\times M}}$ and ${\textstyle \mathbf {V} \in \mathbb {C} ^{T\times T}}$ are unitary matrices and ${\textstyle \mathbf {\Sigma } }$ is a diagonal matrix of size ${\textstyle M\times T}$ , that holds the singular values from the largest (top left) in descending order. The operator ${\textstyle \dagger }$ denotes the complex-conjugate transpose (Hermitian transpose).

Let us assume that ${\textstyle T\geq M}$ . Notice that we have ${\textstyle K}$ input signals. If there was no noise, there would only be ${\textstyle K}$ non-zero singular values. We assume that the ${\textstyle K}$ largest singular values stem from these input signals and other singular values are presumed to stem from noise. The matrices in SVD of ${\textstyle \mathbf {Y} }$ can be partitioned into submatrices, where some submatrices correspond to the signal subspace and some correspond to the noise subspace. ${\begin{aligned}\mathbf {U} ={\begin{bmatrix}\mathbf {U} _{\mathrm {S} }&\mathbf {U} _{\mathrm {N} }\end{bmatrix}},&&\mathbf {\Sigma } ={\begin{bmatrix}\mathbf {\Sigma } _{\mathrm {S} }&\mathbf {0} &\mathbf {0} \\\mathbf {0} &\mathbf {\Sigma } _{\mathrm {N} }&\mathbf {0} \end{bmatrix}},&&\mathbf {V} ={\begin{bmatrix}\mathbf {V} _{\mathrm {S} }&\mathbf {V} _{\mathrm {N} }&\mathbf {V} _{\mathrm {0} }\end{bmatrix}}\end{aligned}},$ where ${\textstyle \mathbf {U} _{\mathrm {S} }\in \mathbb {C} ^{M\times K}}$ and ${\textstyle \mathbf {V} _{\mathrm {S} }\in \mathbb {C} ^{N\times K}}$ contain the first ${\textstyle K}$ columns of ${\textstyle \mathbf {U} }$ and ${\textstyle \mathbf {V} }$ , respectively and ${\textstyle \mathbf {\Sigma } _{\mathrm {S} }\in \mathbb {C} ^{K\times K}}$ is a diagonal matrix comprising the ${\textstyle K}$ largest singular values.

Thus, The SVD can be written as $\mathbf {Y} =\mathbf {U} _{\mathrm {S} }\mathbf {\Sigma } _{\mathrm {S} }\mathbf {V} _{\mathrm {S} }^{\dagger }+\mathbf {U} _{\mathrm {N} }\mathbf {\Sigma } _{\mathrm {N} }\mathbf {V} _{\mathrm {N} }^{\dagger },$ where ${\textstyle \mathbf {U} _{\mathrm {S} }}$ , ⁣ ${\textstyle \mathbf {V} _{\mathrm {S} }}$ , and ${\textstyle \mathbf {\Sigma } _{\mathrm {S} }}$ represent the contribution of the input signal ${\textstyle x_{k}[t]}$ to ${\textstyle \mathbf {Y} }$ . We term ${\textstyle \mathbf {U} _{\mathrm {S} }}$ the signal subspace. In contrast, ${\textstyle \mathbf {U} _{\mathrm {N} }}$ , ${\textstyle \mathbf {V} _{\mathrm {N} }}$ , and ${\textstyle \mathbf {\Sigma } _{\mathrm {N} }}$ represent the contribution of noise ${\textstyle n_{m}[t]}$ to ${\textstyle \mathbf {Y} }$ .

Hence, from the system model, we can write ${\textstyle \mathbf {A} \mathbf {X} =\mathbf {U} _{\mathrm {S} }\mathbf {\Sigma } _{\mathrm {S} }\mathbf {V} _{\mathrm {S} }^{\dagger }}$ and ${\textstyle \mathbf {N} =\mathbf {U} _{\mathrm {N} }\mathbf {\Sigma } _{\mathrm {N} }\mathbf {V} _{\mathrm {N} }^{\dagger }}$ . Also, from the former, we can write $\mathbf {U} _{\mathrm {S} }=\mathbf {A} \mathbf {F} ,$ where ${\mathbf {F} }=\mathbf {X} \mathbf {V} _{\mathrm {S} }\mathbf {\Sigma } _{\mathrm {S} }^{-1}$ . In the sequel, it is only important that there exist such an invertible matrix ${\textstyle \mathbf {F} }$ and its actual content will not be important.

Note: The signal subspace can also be extracted from the spectral decomposition of the auto-correlation matrix of the measurements, which is estimated as $\mathbf {R} _{\mathrm {YY} }={\frac {1}{T}}\sum _{t=1}^{T}\mathbf {y} [t]\mathbf {y} [t]^{\dagger }={\frac {1}{T}}\mathbf {Y} \mathbf {Y} ^{\dagger }={\frac {1}{T}}\mathbf {U} {\mathbf {\Sigma } \mathbf {\Sigma } ^{\dagger }}\mathbf {U} ^{\dagger }={\frac {1}{T}}\mathbf {U} _{\mathrm {S} }\mathbf {\Sigma } _{\mathrm {S} }^{2}\mathbf {U} _{\mathrm {S} }^{\dagger }+{\frac {1}{T}}\mathbf {U} _{\mathrm {N} }\mathbf {\Sigma } _{\mathrm {N} }^{2}\mathbf {U} _{\mathrm {N} }^{\dagger }.$

Estimation of radial frequencies[edit]

We have established two expressions so far: ${\textstyle \mathbf {J} _{2}\mathbf {A} =\mathbf {J} _{1}\mathbf {A} \mathbf {H} }$ and ${\textstyle \mathbf {U} _{\mathrm {S} }=\mathbf {A} \mathbf {F} }$ . Now, ${\begin{aligned}\mathbf {J} _{2}\mathbf {A} =\mathbf {J} _{1}\mathbf {A} \mathbf {H} \implies \mathbf {J} _{2}(\mathbf {U} _{\mathrm {S} }\mathbf {F} ^{-1})=\mathbf {J} _{1}(\mathbf {U} _{\mathrm {S} }\mathbf {F} ^{-1})\mathbf {H} \implies \mathbf {S} _{2}=\mathbf {S} _{1}\mathbf {P} ,\end{aligned}}$ where $\mathbf {S} _{1}=\mathbf {J} _{1}\mathbf {U} _{\mathrm {S} }$ and $\mathbf {S} _{2}=\mathbf {J} _{2}\mathbf {U} _{\mathrm {S} }$ denote the truncated signal sub spaces, and $\mathbf {P} =\mathbf {F} ^{-1}\mathbf {H} \mathbf {F} .$ The above equation has the form of an eigenvalue decomposition, and the phases of eigenvalues in the diagonal matrix $\mathbf {H}$ are used to estimate the radial frequencies.

Thus, after solving for $\mathbf {P}$ in the relation $\mathbf {S} _{2}=\mathbf {S} _{1}\mathbf {P}$ , we would find the eigenvalues ${\textstyle \lambda _{1},\ \lambda _{2},\ \ldots ,\ \lambda _{K}}$ of $\mathbf {P}$ , where $\lambda _{k}=\alpha _{k}\mathrm {e} ^{j\omega _{k}}$ , and the radial frequencies $\omega _{1},\ \omega _{2},\ \ldots ,\ \omega _{K}$ are estimated as the phases (argument) of the eigenvalues.

Remark: In general, $\mathbf {S} _{1}$ is not invertible. One can use the least squares estimate ${\mathbf {P} }=(\mathbf {S} _{1}^{\dagger }{\mathbf {S} _{1}})^{-1}\mathbf {S} _{1}^{\dagger }{\mathbf {S} _{2}}$ . An alternative would be the total least squares estimate.

Algorithm summary[edit]

Input: Measurements ${\textstyle \mathbf {Y} :=[\,\mathbf {y} [1]\,\ \mathbf {y} [2]\,\ \dots \,\ \mathbf {y} [T]\,]}$ , the number of input signals ${\textstyle K}$ (estimate if not already known).

Compute the singular value decomposition (SVD) of ${\textstyle \mathbf {Y} =\mathbf {U} \mathbf {\Sigma } \mathbf {V} ^{\dagger }}$ and extract the signal subspace ${\textstyle \mathbf {U} _{\mathrm {S} }\in \mathbb {C} ^{M\times K}}$ as the first ${\textstyle K}$ columns of ${\textstyle \mathbf {U} }$ .
Compute ${\textstyle \mathbf {S} _{1}=\mathbf {J} _{1}\mathbf {U} _{\mathrm {S} }}$ and ${\textstyle \mathbf {S} _{2}=\mathbf {J} _{2}\mathbf {U} _{\mathrm {S} }}$ , where $\mathbf {J} _{1}=[\mathbf {I} _{M-1}\quad \mathbf {0} ]$ and $\mathbf {J} _{2}=[\mathbf {0} \quad \mathbf {I} _{M-1}]$ .
Solve for ${\textstyle \mathbf {P} }$ in ${\textstyle \mathbf {S} _{2}=\mathbf {S} _{1}\mathbf {P} }$ (see the remark above).
Compute the eigenvalues ${\textstyle \lambda _{1},\lambda _{2},\ldots ,\lambda _{K}}$ of ${\textstyle \mathbf {P} }$ .
The phases of the eigenvalues ${\textstyle \lambda _{k}=\alpha _{k}\mathrm {e} ^{j\omega _{k}}}$ provide the radial frequencies ${\textstyle \omega _{k}}$ , i.e., ${\textstyle \omega _{k}=\arg \lambda _{k}}$

Notes[edit]

Choice of selection matrices[edit]

In the derivation above, the selection matrices $\mathbf {J} _{1}=[\mathbf {I} _{M-1}\quad \mathbf {0} ]$ and $\mathbf {J} _{2}=[\mathbf {0} \quad \mathbf {I} _{M-1}]$ were used. However, any appropriate matrices ${\textstyle \mathbf {J} _{1}}$ and $\mathbf {J} _{2}$ may be used as long as the rotational invariance ${\textstyle (}$ i.e., $\mathbf {J} _{2}\mathbf {a} (\omega _{k})=e^{-j\omega _{k}}\mathbf {J} _{1}\mathbf {a} (\omega _{k})$ ${\textstyle )}$ , or some generalization of it (see below) holds; accordingly, the matrices ${\textstyle \mathbf {J} _{1}\mathbf {A} }$ and ${\textstyle \mathbf {J} _{2}\mathbf {A} }$ may contain any rows of ${\textstyle \mathbf {A} }$ .

Generalized rotational invariance[edit]

The rotational invariance used in the derivation may be generalized. So far, the matrix $\mathbf {H}$ has been defined to be a diagonal matrix that stores the sought-after complex exponentials on its main diagonal. However, $\mathbf {H}$ may also exhibit some other structure.^[3] For instance, it may be an upper triangular matrix. In this case, ${\textstyle \mathbf {P} =\mathbf {F} ^{-1}\mathbf {H} \mathbf {F} }$ constitutes a triangularization of $\mathbf {P}$ .

References[edit]

^ Paulraj, A.; Roy, R.; Kailath, T. (1985), "Estimation Of Signal Parameters Via Rotational Invariance Techniques - Esprit", Nineteenth Asilomar Conference on Circuits, Systems and Computers, pp. 83–89, doi:10.1109/ACSSC.1985.671426, ISBN 978-0-8186-0729-5, S2CID 2293566
^ Volodymyr Vasylyshyn. The direction of arrival estimation using ESPRIT with sparse arrays.// Proc. 2009 European Radar Conference (EuRAD). – 30 Sept.-2 Oct. 2009. - Pp. 246 - 249. - [1]
^ Hu, Anzhong; Lv, Tiejun; Gao, Hui; Zhang, Zhang; Yang, Shaoshi (2014). "An ESPRIT-Based Approach for 2-D Localization of Incoherently Distributed Sources in Massive MIMO Systems". IEEE Journal of Selected Topics in Signal Processing. 8 (5): 996–1011. arXiv:1403.5352. Bibcode:2014ISTSP...8..996H. doi:10.1109/JSTSP.2014.2313409. ISSN 1932-4553. S2CID 11664051.