Three-axis hall angle sensor with accuracy of 0.3°

What is claimed is: 1 . A three-axis Hall angle sensor, comprising: four horizontal Hall elements and eight vertical Hall elements disposed on a plane, wherein: the eight vertical Hall elements are divided into two groups, an X-direction group and a Y-direction group, the X-direction group comprising four vertical Hall elements X 1 , X 2 , X 3 and X 4 , and the Y-direction group comprising four vertical Hall elements Y 1 , Y 2 , Y 3 and Y 4 ; each vertical Hall element comprises four three-contact Hall components, and the four three-contact Hall components are connected end-to-end in series; the four horizontal Hall elements comprising Z 1 , Z 2 , Z 3 and Z 4 are in a 2×2 array arrangement; in the X-direction group, X 1 and X 2 are located on a left side of the four horizontal Hall elements; X 2 is located between X 1 and four horizontal Hall elements; X 3 and X 4 are located on a right side of the four horizontal Hall elements, and X 3 is located between X 4 and the four horizontal Hall elements; X 1 comprises four three-contact Hall components, in which middle electrodes are A X1 , B X1 , C X1 and D X1 in sequence; X 2 comprises four three-contact Hall components, in which middle electrodes are A X2 , B X2 , C X2 , and D X2 in sequence; X 3 comprises four three-contact Hall components, in which middle electrodes are A X3 , B X3 , C X3 and D X3 in sequence; X 4 comprises four three-contact Hall components, in which middle electrodes are A X4 , B X4 , C X4 and D X4 in sequence; when measuring an X-direction magnetic field, for a first vertical Hall element X 1 , applying a current bias between contact electrodes of B X1 and D X1 , and measuring a Hall voltage V HallX1 between contact electrodes of A X1 and C X1 ; for a second vertical Hall element X 2 , applying a current bias between contact electrodes of B X2 and D X2 , and simultaneously measuring a Hall voltage V HallX2 generated between A X2 and C X2 ; for a third vertical Hall element X 3 , applying a current bias between contact electrodes of C X3 and A X3 , and measuring a Hall voltage V HallX3 between contact electrodes of B X3 and D X3 ; for a fourth vertical Hall element X 4 , applying a current bias between the A X4 and C X4 contact electrodes, and measuring a Hall voltage V HallX4 between contact electrodes of D X4 and B X4 ; in a Y direction, vertical Hall elements Y 1 and Y 2 are located on an upper side of the four horizontal Hall elements, and Y 2 is located between Y 1 and the four horizontal Hall elements; vertical Hall elements Y 3 and Y 4 are located on a lower side of the four horizontal Hall elements, and Y 3 is located between Y 4 and the four horizontal Hall elements; Y 1 comprises four three-contact Hall components, in which middle electrodes are A Y1 , B Y1 , C Y1 and D Y1 in sequence; Y 2 comprises four three-contact Hall components, in which intermediate electrodes are A Y2 , B Y2 , C Y2 and D Y2 in sequence; Y 3 comprise four three-contact Hall components, in which intermediate electrodes are A Y3 , B Y3 , C Y3 and D Y3 in sequence; Y 4 comprises four three-contact Hall components, and intermediate electrodes are A Y4 , B Y4 , C Y4 and D Y4 in sequence; when measuring a magnetic field in the Y direction, the following steps are taken: for a first vertical Hall element Y 1 , applying a current bias between D Y1 and B Y1 , and measuring a Hall voltage V HallY1 between contact electrodes of A Y1 and C Y1 ; for a second vertical Hall element Y 2 , applying a current bias between B Y2 and D Y2 , and simultaneously measuring a sensing Hall voltage V HallY2 generated between A Y2 and C Y2 ; for a third vertical Hall element Y 3 , applying a current bias between contact electrodes of A Y3 and C Y3 , and measuring a Hall voltage V HallY3 between contact electrodes of D Y3 and B Y3 ; for a fourth vertical Hall element Y 4 , applying a current bias between the B Y4 and D Y4 contact electrodes, then measuring a Hall voltages V HallY4 between contact electrodes of C Y4 and A Y4 ; each horizontal Hall element comprises four electrodes: A, B, C and D; a first horizontal Hall element Z 1 is applied with a bias current between electrodes A Z1 and C Z1 , and measuring a Hall voltage V HallZ1 generated between electrodes D Z1 and B Z1 ; for a second horizontal Hall element Z 2 , applying a current bias between electrodes B Z2 and D Z2 , then measuring a Hall voltage V HallZ2 between electrodes A Z2 and C Z2 ; for a third horizontal Hall element Z 3 , applying a current bias between electrodes C Z3 and A Z3 , then measuring a Hall voltage V HallZ3 between electrodes B Z3 and D Z3 ; for a fourth horizontal Hall element Z 4 , applying a current bias between electrodes D Z4 and B Z4 , and measuring a Hall voltage V HallZ4 between electrodes C Z4 and A Z4 ; and the four identical Hall elements, Z 1 , Z 2 , Z 3 , Z 4 , are connected together by orthogonal coupling. 2 . The three-axis Hall angle sensor of claim 1 , wherein a current transmission equation of the three-axis Hall angle sensor J n is: J n = J n ⁢ 0 · M ( 1 ) M = 1 1 + a 2 + b 2 + c 2 ⁢ ( 1 + a 2 ab - c ca + b c + ab