File:Ringmagnet compasses.svg

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Original file ‎(SVG file, nominally 600 × 600 pixels, file size: 25 KB)

Captions

English

Compass needles around a ringmagnet

Summary

Description

English: Pointings of magnetic compasses around a cylindrical ringmagnet. The direction of each compass needle is computed with the exact formula, given in the source code. The magnet consists of a flat cylinder of R/L=2 with a cylindrical hole of radius r/R=1/2 and is homogeneously magnetized along the cylinder axis. The north-half of the magnet is painted red, whereas the south-half is green.

Date

16 December 2022

Source

Own work

Author

Geek3

SVG development

The SVG code is valid.

This vector image was created with Python.

Source code

Python code

Python svgwrite code

#!/usr/bin/python3
# -*- coding: utf8 -*-

try:
    import svgwrite
except ImportError:
    print('requires svgwrite library: https://pypi.org/project/svgwrite/')
    # documentation at https://svgwrite.readthedocs.io/
    exit(1)


import numpy as np
from scipy.integrate import solve_ivp
from scipy.optimize import minimize
from math import *


name = 'Ringmagnet_compasses'
size = 600, 600
R1 = 100
R2 = 200 - 1e-6
L = 100
needles_d = 40.
needle_w = 6.
needle_l = 16.
needle_c = 2.5


def cel(kc, p, a, b):
    """
    Bulirsch complete elliptic integral
    """
    
    if kc == 0.:
        return nan
    
    tol = 1e-9 # actual relative error will be tol**2
    k = kc = fabs(kc)
    m = 1.
    
    if p > 0.:
        p = sqrt(p)
        b /= p
    else:
        f = kc * kc
        g = 1. - p
        q = (1. - f) * (b - a * p)
        f -= p
        p = sqrt(f / g)
        a = (a - b) / g
        b = a * p - q / (g * g * p)
    
    for i in range(11):
        f = a
        a += b / p
        g = k / p
        b = 2. * (b + f * g)
        p += g
        g = m
        m += kc
        
        if fabs(g - kc) <= g * tol:
            break
        
        kc = 2. * sqrt(k)
        k = kc * m
    
    return pi * .5 * (a * m + b) / (m * (m + p))


def Bfield_barmagnet(xy, R, L, M):
    # www.doi.org/10.1119/1.3256157
    rho, z = xy
    rho0 = 1.
    if rho < 0.:
        rho = -rho
        rho0 = -1.
    Rm, Rp = R - rho, R + rho
    zm, zp = z - L / 2, z + L / 2
    Rmzm = hypot(Rm, zm)
    Rmzp = hypot(Rm, zp)
    Rpzm = hypot(Rp, zm)
    Rpzp = hypot(Rp, zp)
    g = Rm / Rp
    km = Rmzm / Rpzm
    kp = Rmzp / Rpzp
    Frhom = cel(km, 1., 1., -1.) / Rpzm
    Frhop = cel(kp, 1., 1., -1.) / Rpzp
    Fzm = cel(km, g * g, 1., g) * zm / Rpzm
    Fzp = cel(kp, g * g, 1., g) * zp / Rpzp
    return M * R / pi * np.array((rho0 * (Frhop - Frhom), (Fzp - Fzm) / Rp))


def Bfield(xy):
    return Bfield_barmagnet(xy, R2, L, 1.) - Bfield_barmagnet(xy, R1, L, 1.)


# draw the magnet
doc = svgwrite.Drawing(name + '.svg', profile='full', size=size)
doc.set_desc(name, 'https://commons.wikimedia.org/wiki/File:' + name +
    '.svg\nrights: Creative Commons Attribution ShareAlike license')
clip = doc.defs.add(doc.clipPath(id='image_clip'))
clip.add(doc.rect(insert=(-size[0]/2., -size[1]/2.), size=size))
doc.add(doc.rect(id='background', insert=(0, 0), size=size, fill='#ffffff', stroke='none'))
g = doc.add(doc.g(id='image', clip_path='url(#image_clip)',
    transform='translate({:.0f}, {:.0f}) scale(1,-1)'.format(size[0]/2., size[1]/2.)))
needle = doc.defs.add(doc.g(id='needle'))
needle.add(doc.path(d='M {:.3f},{:.3f} L {:.3f},{:.3f} L {:.3f},{:.3f} L {:.3f},{:.3f} Z'.format(
    -needle_w, 0, 0, needle_l, needle_w, 0, 0, -needle_l),
    fill='#00cc00', stroke='none'))
needle.add(doc.path(d='M {:.3f},{:.3f} L {:.3f},{:.3f} L {:.3f},{:.3f} Z'.format(
    -needle_w, 0, 0, needle_l, needle_w, 0),
    fill='#ff0000', stroke='none'))
needle.add(doc.path(d='M {:.3f},{:.3f} L {:.3f},{:.3f} L {:.3f},{:.3f} L {:.3f},{:.3f} Z'.format(
    -needle_w, 0, 0, needle_l, needle_w, 0, 0, -needle_l),
    fill='none', stroke='#000000', stroke_width=2,
    stroke_linejoin='miter', stroke_miterlimit=10))
needle.add(doc.circle(center=(0, 0), r='{:.3f}'.format(needle_c),
    fill='#ffffff', stroke='#000000', stroke_width=2))
magnet_back = g.add(doc.g(id='magnet_back'))
needles = g.add(doc.g(id='needles'))
magnet_front = g.add(doc.g(id='magnet_front'))
mgrad = doc.defs.add(doc.linearGradient(id="magnetGrad",
    start=(0,0), end=(1,0), gradientUnits="objectBoundingBox"))
for c, of, op in [['#000000', '0', '0.33'], ['#ffffff', '0.4', '0.2'],
        ['#ffffff', '0.75', '0.5'], ['#ffffff', '0.93', '0.125'],
        ['#000000', '1', '0.125']]:
    mgrad.add_stop_color(of, c, op)
for x0, x1, isbg in [[-R2, -R1, False], [-R1, R1, True], [R1, R2, False]]:
    if isbg:
        magnet = magnet_back
        fill = 'url(#magnetGrad)'
        colors = ['#00cc00', '#ff0000']
    else:
        magnet = magnet_front
        fill = 'none'
        colors = ['#49da49', '#ff4949']
    for i in [0, 1]:
        magnet.add(doc.rect(insert=(x0, [-L/2, 0][i]), size=(x1-x0, [L, L/2][i]),
            fill=colors[i], stroke='none'))
    magnet.add(doc.rect(insert=(x0, -L/2), size=(x1 - x0, L), fill=fill,
            stroke='#000000', stroke_width=4, stroke_linejoin='miter'))


needles_nx = round(size[0] / needles_d)
needles_ny = round(size[1] / needles_d)
needles_x = (np.arange(needles_nx) + 0.5) * needles_d - size[0] / 2.
needles_y = (np.arange(needles_ny) + 0.5) * needles_d - size[1] / 2.

for y in needles_y:
    for x in needles_x:
        B = Bfield([x, y])
        direction = atan2(B[1], B[0])
        needles.add(doc.use(href='#needle', insert=(0, 0),
            transform='translate({:.3f},{:.3f}) rotate({:.2f})'.format(
            x, y, degrees(direction-pi/2))))


doc.save(pretty=True)

Licensing

I, the copyright holder of this work, hereby publish it under the following license:

This file is licensed under the Creative Commons Attribution-Share Alike 4.0 International license.

You are free:

to share – to copy, distribute and transmit the work
to remix – to adapt the work

Under the following conditions:

attribution – You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use.
share alike – If you remix, transform, or build upon the material, you must distribute your contributions under the same or compatible license as the original.

File history

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	Date/Time	Thumbnail	Dimensions	User	Comment
current	15:42, 16 December 2022		600 × 600 (25 KB)	Geek3 (talk \| contribs)	Uploaded own work with UploadWizard

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Short title	Ringmagnet_compasses
Image title	https://commons.wikimedia.org/wiki/File:Ringmagnet_compasses.svg rights: Creative Commons Attribution ShareAlike license
Width	600
Height	600

File:Ringmagnet compasses.svg

Captions

Captions

Summary

Python code

Licensing

File history

File usage on Commons

Metadata

Structured data

Items portrayed in this file

depicts

magnetic needle

creator

some value

copyright status

copyrighted

copyright license

Creative Commons Attribution-ShareAlike 4.0 International

inception

16 December 2022

media type

image/svg+xml

source of file

original creation by uploader