In the arrangement shown in the figure, 3.51 A current flows in the same direction from the coils with 320 windings and a radius of 7.50 cm. In this case, when we place the hall probe at a point 3.00 cm from the center of the coils, a deviation of 39 μA is observed in the microammeter connected to the hall probe. Since the microammeter deviates by 51.2 μA when we hold the Hall probe at a distance of 3.00 cm from a bar magnet, calculate the magnetic field of the bar magnet at this distance. (μ0 = 4π x 10-7 T.m/A, π = 3.14) 9 VN sarımN sarımPilMikroampermetreHall ProbGuς KaynagŞekilde gösterilen düzenekte birinde 320 sarım olan ve 7.50 cm yarıçaplı bobinlerden aynı yönde 3.51 A büyüklüğünde akım geçmektedir. Budurumda bobinlerin merkezinden 3.00 cm uzaklıktaki bir noktaya hall probu yerleştirdiğimizde hall probuna bağlı olan mikroampermetrede 39HA' lik sapma gözlenmektedir. Hall probunu bir çubuk mıknatısa 3.00 cm uzaklıkta tuttuğumuzda mikroampermetre 51.2 µA' lik sapmagösterdiğine göre bu uzaklıkta çubuk mıknatısın sahip olduğu manyetik alanı hesaplayınız.(Ho = 4M x 10-7 T.m/A, T = 3.14)

Given: Current in a coil = 3.51 A Radius of coil = 7.50 cm = 7.5 x 10-2 m Distance of hall probe…

In the arrangement shown in the figure, 3.51 A current flows in the same direction from the coils with 320 windings and a radius of 7.50 cm. In this case, when we place the hall probe at a point 3.00 cm from the center of the coils, a deviation of 39 μA is observed in the microammeter connected to the hall probe. Since the microammeter deviates by 51.2 μA when we hold the Hall probe at a distance of 3.00 cm from a bar magnet, calculate the magnetic field of the bar magnet at this distance. (μ0 = 4π x 10-7 T.m/A, π = 3.14)

In the arrangement shown in the figure, 3.51 A current flows in the same direction from the coils with 320 windings and a radius of 7.50 cm. In this case, when we place the hall probe at a point 3.00 cm from the center of the coils, a deviation of 39 μA is observed in the microammeter connected to the hall probe. Since the microammeter deviates by 51.2 μA when we hold the Hall probe at a distance of 3.00 cm from a bar magnet, calculate the magnetic field of the bar magnet at this distance. (μ0 = 4π x 10-7 T.m/A, π = 3.14)

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