Physics equations/22-Magnetism/Q:AmpereLawCALC/More practice

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 52A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7.5) to the point (7.5,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 96A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-6.6, 6.6) to the point (6.6, 6.6).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 33A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,9.5) to the point (9.5,9.5).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 94A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,6.2) to (+∞,6.2).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 78A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,4.6) to the point (4.6,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 91A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-9.6, 9.6) to the point (9.6, 9.6).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 37A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,9) to the point (9,9).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 93A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,4.1) to (+∞,4.1).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 83A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7.4) to the point (7.4,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 74A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-5.7, 5.7) to the point (5.7, 5.7).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 88A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,6.6) to the point (6.6,6.6).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 74A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,9) to (+∞,9).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 37A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,8.4) to the point (8.4,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 33A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-6.6, 6.6) to the point (6.6, 6.6).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 33A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,9.8) to the point (9.8,9.8).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 67A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,9.4) to (+∞,9.4).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 92A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,6.4) to the point (6.4,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 74A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-7.4, 7.4) to the point (7.4, 7.4).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 92A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,5.3) to the point (5.3,5.3).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 31A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,9.2) to (+∞,9.2).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 87A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,9.3) to the point (9.3,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 96A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-6.4, 6.4) to the point (6.4, 6.4).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 86A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,5) to the point (5,5).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 74A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,8.2) to (+∞,8.2).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 47A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,9) to the point (9,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 65A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-4.9, 4.9) to the point (4.9, 4.9).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 46A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7.9) to the point (7.9,7.9).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 69A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,5.8) to (+∞,5.8).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 55A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,8.7) to the point (8.7,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 40A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-9.4, 9.4) to the point (9.4, 9.4).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 50A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7) to the point (7,7).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 85A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,8) to (+∞,8).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 92A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7.1) to the point (7.1,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 77A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-9.8, 9.8) to the point (9.8, 9.8).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 39A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,8.5) to the point (8.5,8.5).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 88A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,8.7) to (+∞,8.7).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 40A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,6.7) to the point (6.7,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 70A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-8.7, 8.7) to the point (8.7, 8.7).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 59A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7.2) to the point (7.2,7.2).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 94A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,9.4) to (+∞,9.4).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 54A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,5.4) to the point (5.4,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 87A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-6.1, 6.1) to the point (6.1, 6.1).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 42A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,4.2) to the point (4.2,4.2).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 96A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,8.1) to (+∞,8.1).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 48A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,9.3) to the point (9.3,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 94A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-5.8, 5.8) to the point (5.8, 5.8).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 36A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,8.6) to the point (8.6,8.6).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 36A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,8.3) to (+∞,8.3).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 74A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,4.1) to the point (4.1,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 63A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-9.3, 9.3) to the point (9.3, 9.3).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 38A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,6.7) to the point (6.7,6.7).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 76A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,5.8) to (+∞,5.8).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 91A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7.3) to the point (7.3,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 82A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-9.3, 9.3) to the point (9.3, 9.3).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 89A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,4.8) to the point (4.8,4.8).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 44A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,5) to (+∞,5).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 94A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,8.4) to the point (8.4,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 51A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-7, 7) to the point (7, 7).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 48A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,8.4) to the point (8.4,8.4).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 39A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,8.5) to (+∞,8.5).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 63A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,4.6) to the point (4.6,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 88A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-8.1, 8.1) to the point (8.1, 8.1).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 49A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,9.8) to the point (9.8,9.8).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 43A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,5.8) to (+∞,5.8).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 43A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7.1) to the point (7.1,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 51A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-6.8, 6.8) to the point (6.8, 6.8).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 94A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,5.3) to the point (5.3,5.3).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 31A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,9.4) to (+∞,9.4).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 99A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,6.2) to the point (6.2,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 74A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-6.4, 6.4) to the point (6.4, 6.4).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 31A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7.3) to the point (7.3,7.3).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 66A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,5.5) to (+∞,5.5).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 85A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,9.8) to the point (9.8,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 71A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-8.6, 8.6) to the point (8.6, 8.6).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 81A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,7.9) to the point (7.9,7.9).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 76A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,9.6) to (+∞,9.6).

1 H is defined by, B=μ₀H, where B is magnetic field. A current of 40A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,6.6) to the point (6.6,0).

2 H is defined by, B=μ₀H, where B is magnetic field. A current of 68A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (-6.4, 6.4) to the point (6.4, 6.4).

3 H is defined by, B=μ₀H, where B is magnetic field. A current of 58A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from the point (0,8.5) to the point (8.5,8.5).

4 H is defined by, B=μ₀H, where B is magnetic field. A current of 67A passes along the z-axis. Use symmetry to find the integral, ${\displaystyle \int {\vec {H}}\cdot {\vec {d\ell }}}$ , from (-∞,6.9) to (+∞,6.9).