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introduced --> explained (as Alexandre Eremenko pointed out, the concept was introduced earlier)
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Carlo Beenakker
Carlo Beenakker
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The name refers to the concept of an anharmonic ratio, or cross-ratio. Four points $A,B,C,D$ are called equianharmonic if their cross-ratio is a cube root of 1. In that case the 6 cross-ratios obtained by combining the four points in all possible ways are the same ("equal anharmonic ratio" = "equianharmonic").

The curve $y^2=x^3-1=(x-p_1)(x-p_2)(x-p_3)$ has $p_1=1$, $p_2=e^{i2\pi/3}$, $p_3=e^{i4\pi/3}$ equal to the three cube roots of 1. The four intersection points of a line with the four tangents, drawn from any point on the curve, are equianharmonic.

If you read German, you might want to know how Wiener described this when he introducedexplained the concept in 1901:

enter image description here

[source]

The name refers to the concept of an anharmonic ratio, or cross-ratio. Four points $A,B,C,D$ are called equianharmonic if their cross-ratio is a cube root of 1. In that case the 6 cross-ratios obtained by combining the four points in all possible ways are the same ("equal anharmonic ratio" = "equianharmonic").

The curve $y^2=x^3-1=(x-p_1)(x-p_2)(x-p_3)$ has $p_1=1$, $p_2=e^{i2\pi/3}$, $p_3=e^{i4\pi/3}$ equal to the three cube roots of 1. The four intersection points of a line with the four tangents, drawn from any point on the curve, are equianharmonic.

If you read German, you might want to know how Wiener described this when he introduced the concept in 1901:

enter image description here

[source]

The name refers to the concept of an anharmonic ratio, or cross-ratio. Four points $A,B,C,D$ are called equianharmonic if their cross-ratio is a cube root of 1. In that case the 6 cross-ratios obtained by combining the four points in all possible ways are the same ("equal anharmonic ratio" = "equianharmonic").

The curve $y^2=x^3-1=(x-p_1)(x-p_2)(x-p_3)$ has $p_1=1$, $p_2=e^{i2\pi/3}$, $p_3=e^{i4\pi/3}$ equal to the three cube roots of 1. The four intersection points of a line with the four tangents, drawn from any point on the curve, are equianharmonic.

If you read German, you might want to know how Wiener described this when he explained the concept in 1901:

enter image description here

[source]

added 250 characters in body
Source Link
Carlo Beenakker
Carlo Beenakker
  • 188.1k
  • 18
  • 448
  • 651

The name (introduced by Wiener, 1901), refers to the concept of an anharmonic ratio, or cross-ratio. Four points $A,B,C,D$ are called equianharmonic if their cross-ratio is a cube root of 1. In that case the 6 cross-ratios obtained by combining the four points in all possible ways are the same ("equal anharmonic ratio" = "equianharmonic").

The equianharmonic curve $y^2=x^3-1=(x-p_1)(x-p_2)(x-p_3)$ has $p_1=1$, $p_2=e^{i2\pi/3}$, $p_3=e^{i4\pi/3}$ equal to the three cube roots of 1. The four intersection points of a line with the four tangents, drawn from any point on the curve, are equianharmonic.

If you read German, you might want to know how Wiener described this when he introduced the concept in 1901:

enter image description here

[source]

The name (introduced by Wiener, 1901), refers to the concept of an anharmonic ratio, or cross-ratio. Four points $A,B,C,D$ are called equianharmonic if their cross-ratio is a cube root of 1. In that case the 6 cross-ratios obtained by combining the four points in all possible ways are the same ("equal anharmonic ratio" = "equianharmonic").

The equianharmonic curve $y^2=x^3-1=(x-p_1)(x-p_2)(x-p_3)$ has $p_1=1$, $p_2=e^{i2\pi/3}$, $p_3=e^{i4\pi/3}$ equal to the three cube roots of 1.

The name refers to the concept of an anharmonic ratio, or cross-ratio. Four points $A,B,C,D$ are called equianharmonic if their cross-ratio is a cube root of 1. In that case the 6 cross-ratios obtained by combining the four points in all possible ways are the same ("equal anharmonic ratio" = "equianharmonic").

The curve $y^2=x^3-1=(x-p_1)(x-p_2)(x-p_3)$ has $p_1=1$, $p_2=e^{i2\pi/3}$, $p_3=e^{i4\pi/3}$ equal to the three cube roots of 1. The four intersection points of a line with the four tangents, drawn from any point on the curve, are equianharmonic.

If you read German, you might want to know how Wiener described this when he introduced the concept in 1901:

enter image description here

[source]

added 196 characters in body
Source Link
Carlo Beenakker
Carlo Beenakker
  • 188.1k
  • 18
  • 448
  • 651

The name (introduced by Wiener, 1901), refers to the concept of an anharmonic ratio, or cross-ratio. Four points $A,B,C,D$ are called equianharmonic if their cross-ratio is a cube root of 1. In that case the 6 cross-ratios obtained by combining the four points in all possible ways are the same ("equal anharmonic ratio" = "equianharmonic").

The equianharmonic curve $y^2=x^3-1=(x-p_1)(x-p_2)(x-p_3)$ has $p_1=1$, $p_2=e^{i2\pi/3}$, $p_3=e^{i4\pi/3}$ equal to the three cube roots of 1.

The name (introduced by Wiener, 1901), refers to the concept of an anharmonic ratio, or cross-ratio. Four points $A,B,C,D$ are called equianharmonic if their cross-ratio is a cube root of 1. In that case the 6 cross-ratios obtained by combining the four points in all possible ways are the same ("equal anharmonic ratio" = "equianharmonic").

The name (introduced by Wiener, 1901), refers to the concept of an anharmonic ratio, or cross-ratio. Four points $A,B,C,D$ are called equianharmonic if their cross-ratio is a cube root of 1. In that case the 6 cross-ratios obtained by combining the four points in all possible ways are the same ("equal anharmonic ratio" = "equianharmonic").

The equianharmonic curve $y^2=x^3-1=(x-p_1)(x-p_2)(x-p_3)$ has $p_1=1$, $p_2=e^{i2\pi/3}$, $p_3=e^{i4\pi/3}$ equal to the three cube roots of 1.

Source Link
Carlo Beenakker
Carlo Beenakker
  • 188.1k
  • 18
  • 448
  • 651