Abstract
In estimating the two-dimensional (2D) direction-of-arrival (DOA) using a coprime planar array, the main issues are the high complexity of spectral peak search and the limited degree of freedom imposed by the number of sensors. In this paper, we present an algorithm based on the matrix completion theory in coprime planar array that reduces the computational complexity and obtains a high degree of freedom. The algorithm first analyzes the covariance matrix of received signals to estimate the covariance matrix of a virtual uniform rectangular array, which has the same aperture as the coprime planar array. Matrix completion theory is then applied to estimate the missing elements of the virtual array covariance matrix. Finally, a closed-form DOA solution is obtained using the unitary estimation signal parameters via rotational invariance techniques (Unitary-ESPRIT). Simulation results show that the proposed algorithm has a high degree of freedom, enabling the estimation of more signal DOAs than the number of sensors. The proposed algorithm has reduced computational complexity because the spectral peak search is replaced by Unitary-ESPRIT, but attains similarly high levels accuracy to those of the 2D multiple signal classification algorithm.
Highlights
Direction-of-arrival (DOA) estimation is a significant problem in many applications, such as radar [1], underwater acoustics [2], indoor navigation, and so on [3]
For DOA estimation using coprime planar arrays, the problems of high computational complexity and the inadequate array degree of freedom are overcome using an algorithm based on matrix completion theory
This paper has presented a DOA estimation technique for multiple signals using a coprime Thisarray
Summary
Direction-of-arrival (DOA) estimation is a significant problem in many applications, such as radar [1], underwater acoustics [2], indoor navigation, and so on [3]. With the development of technology, the requirement for more precise location determination requires arrays with more sensors and expanded apertures This makes the systems more complicated, and enhances the antenna mutual coupling interference, which increases the estimation errors. For DOA estimation using coprime planar arrays, the problems of high computational complexity and the inadequate array degree of freedom are overcome using an algorithm based on matrix completion theory. Using the unitary estimation signal parameters via rotational invariance techniques (Unitary-ESPRIT), we realize the fast estimation of the 2D DOA angle This algorithm ensures high precise estimation values, as it maintains the same aperture and avoids the spectral peak search, effectively reducing the complexity.
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