helpful to consider the specific example of two solenoids that are wound on a common cylinder. We will take the cylinder to have radius p and length L. Assume that the solenoid is much longer than its radius, so that its field can be determined from Ampère's law throughout its entire length: f B(F) - di – po Iene - I Review | Constants Part A (Figure 1) Part B We will consider the field that arises from solenoid 1, which has ni turns per unit length. The magnetic field due to solenoid 1 passes (entirely, in this case) through solenoid 2, which has ng turns per unit length. Any change in magnetic flux from the field generated by solenoid 1 induces an EMF in solenoid 2 through Faraday's law of induction, What is the flux 1 (t) generated by solenoid 1's magnetic field through a single turn of solenoid 2? Express 1 (t) in terms of B1 (t), quantities given in the introduction, and any needed constants. • View Available Hint(s) $ E(F) - dī = ν ΑΣφ. ? Figure < 1 of 1 (t) = B, (1)^p² Submit Previous Answers Radius p X Incorrect; Try Again; 4 attempts remaining Blue coil: nz turns Part C Complete previous part(s) per unit length Black coil: n turns per unit length Part D Complete previous part(s) Part E Complete previous part(s)
helpful to consider the specific example of two solenoids that are wound on a common cylinder. We will take the cylinder to have radius p and length L. Assume that the solenoid is much longer than its radius, so that its field can be determined from Ampère's law throughout its entire length: f B(F) - di – po Iene - I Review | Constants Part A (Figure 1) Part B We will consider the field that arises from solenoid 1, which has ni turns per unit length. The magnetic field due to solenoid 1 passes (entirely, in this case) through solenoid 2, which has ng turns per unit length. Any change in magnetic flux from the field generated by solenoid 1 induces an EMF in solenoid 2 through Faraday's law of induction, What is the flux 1 (t) generated by solenoid 1's magnetic field through a single turn of solenoid 2? Express 1 (t) in terms of B1 (t), quantities given in the introduction, and any needed constants. • View Available Hint(s) $ E(F) - dī = ν ΑΣφ. ? Figure < 1 of 1 (t) = B, (1)^p² Submit Previous Answers Radius p X Incorrect; Try Again; 4 attempts remaining Blue coil: nz turns Part C Complete previous part(s) per unit length Black coil: n turns per unit length Part D Complete previous part(s) Part E Complete previous part(s)
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Transcribed Image Text:helpful to consider the specific example of two
solenoids that are wound on a common cylinder. We
will take the cylinder to have radius p and length L.
I Review | Constants
Assume that the solenoid is much longer than its
radius, so that its field can be determined from
Part A
Ampère's law throughout its entire length:
f B(F) - di = uo Ienel -
(Figure 1)
Part B
We will consider the field that arises from solenoid 1,
which has ni turns per unit length. The magnetic field
due to solenoid 1 passes (entirely, in this case) through
solenoid 2, which has na turns per unit length. Any
change in magnetic flux from the field generated by
solenoid 1 induces an EMF in solenoid 2 through
Faraday's law of induction,
What is the flux , (t) generated by solenoid 1's magnetic field through a single turn of solenoid 2?
Express d1 (t) in terms of B1 (t), quantities given in the introduction, and any needed constants.
• View Available Hint(s)
ƒÉ(*) - dÏ
Figure
1 of 1
4i (t) = B, (1)1p²
Submit
Previous Answers
Radius p
X Incorrect; Try Again; 4 attempts remaining
Blue coil: n turns
per unit length
Part C Complete previous part(s)
Black coil: n turns
per unit length
Part D Complete previous part(s)
Part E Complete previous part(s)
O Poarson
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