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The Newton-Gauss Line

In mathematics, the Newton-Gauss Line is a property of a theorem known as the Theorem of Complete Quadrilateral, which is a proof within the field of geometry. It is a geometric relation of properties, with a specific interest in the midpoints of line segments within a complete quadrilateral, also known as a tetragram. The theorem states that the midpoints of the three diagonals of a complete quadrilateral lie on a single line. This connecting line is referred to as the Newton-Gauss Line.

The Newton-Gauss Line is very similar to the Newton Line, which follows the same general theorem but uses a convex quadrilateral with at most two parallel sides; this also means instead of having three diagonals, it uses the midpoint of the two s in addition to the point which bisects two lines created by connecting the midpoints of the opposite sides of the quadrilateral.

Theorem of Complete Quadrilateral[edit]

The Theorem of Complete Quadrilateral states that any four lines that are in general position (no two lines are parallel, and no three are concurrent) defines a total of six points; the configuration of these six points, in addition to the line segments belonging to these given lines, are known as the complete quadrilateral. Additionally, a key property is that these 6 points can be split into pairs where their connecting segments do not lie on any of the given 4 lines. These line segments are called diagonals of the quadrilateral. When connecting the midpoints of these diagonals, this forms the Newton-Gauss Line.

Properties[edit]

A complete quadrilateral is the polygon determined by four lines, with there being no three lines that are concurrent, and their six points of intersection. A complete quadrilateral ${\displaystyle ABCDEF}$ (figure 1) has three distinct diagonals: ${\displaystyle AC}$, ${\displaystyle BD}$, and ${\displaystyle EF}$. It should be noted that regular polygons only have two distinct diagonals. The midpoints of these diagonals; ${\displaystyle R}$, ${\displaystyle S}$, and ${\displaystyle T}$, form a line when connected together - this is the Newton-Gauss Line.

One property that is interesting is the distance between the points that make up the Newton-Gauss Line. From the Newton Line, we can see that the outer points of the line are equidistant to the central point of the line. The Newton-Gauss Line does not follow the same equidistance between points. This is due to the extra two points in the complete quadrilateral being able to extend extremely far along the lines, only limited by the angles at which the inner points create.

Applications[edit]

Although the Newton-Gauss Line's applications on a broader spectrum of mathematics is limited, the Newton-Gauss Line is a fundamental concept when dealing with complete quadrilaterals, used to develop an understanding of how quadrilaterals operate and can be manipulated when their vertices are modified. It is also used as a basis for being able to collect a plethora of other information used in the analysis of complete quadrilaterals.

The following are some possible applications of the complete quadrilaterals which are associated with cyclic quadrilaterals, based on the works presented by Barbu and Patrascu.

Angle Equality[edit]

You are able to show angular equality between points on the complete quadrilateral and points lying on the Newton-Gauss Line.

Given any cyclic quadrilateral ${\displaystyle ABCD}$, let point ${\displaystyle F}$ be the point of intersection between the two diagonals ${\displaystyle AC}$ and ${\displaystyle BD}$. Extend out the diagonals ${\displaystyle AB}$ and ${\displaystyle CD}$ until they meet at a point of intersection and let this point be ${\displaystyle E}$. Let the midpoint of the segment ${\displaystyle EF}$ be ${\displaystyle N}$, and let the midpoint of the segment ${\displaystyle BC}$ be ${\displaystyle M}$ (Figure 1).

Theorem[edit]

If the midpoint of the segment ${\displaystyle BF}$ is ${\displaystyle P}$, the Newton-Gauss Line of the complete quadrilateral ${\displaystyle ABCDEF}$ in addition to the line ${\displaystyle PM}$ determines an ${\displaystyle \angle PMN}$ equal to ${\displaystyle \angle EFD}$.

Proof[edit]

First we must show that the triangles ${\displaystyle \triangle NPM}$ and ${\displaystyle \triangle EDF}$ are similar.

Since ${\displaystyle BE\parallel PN}$and additionally ${\displaystyle FC\parallel PM}$,we know ${\displaystyle \angle NPM=\angle EAC}$. Also, ${\displaystyle \left({\frac {BE}{PN}}\right)}$${\displaystyle =\left({\frac {FC}{PN}}\right)=2}$

Within the cyclic quadrilateral ${\displaystyle ABCD}$, we have the set of equalities

${\displaystyle \angle EDF=\angle ADF+\angle EDA=\angle ACB+\angle ABC=\angle EAC}$

Therefore, ${\displaystyle \angle NPM=\angle EDF}$

We let ${\displaystyle R_{1}}$ and ${\displaystyle R_{2}}$ be the radii of the circumcircles of ${\displaystyle \triangle EDB}$ and ${\displaystyle \triangle FCD}$ respectively. If we apply the law of sines to the triangles, we are given:

${\displaystyle {\frac {BE}{FC}}={\frac {2R_{1}sinEDB}{2R_{2}sinFDC}}={\frac {R_{1}}{R_{2}}}={\frac {2R_{1}sinEBD}{2R_{2}sinFCD}}={\frac {DE}{DF}}}$

Since ${\displaystyle BE=2PN}$and also ${\displaystyle FC=2PM}$, we have shown the equality ${\displaystyle {\frac {PN}{PM}}={\frac {DE}{DF}}}$. The similarity of triangles ${\displaystyle PMN}$ and ${\displaystyle DFE}$ follows, and ${\displaystyle \angle NMP=\angle EFD}$.

Remark[edit]

It should be noted that is ${\displaystyle Q}$ is the midpoint of the line segment ${\displaystyle FC}$, by the same reasoning we can show that ${\displaystyle \angle NMQ=\angle EFA}$.

Angle Equality Parallel to the Newton-Gauss Line[edit]

You are able to draw additional parallel lines to the lines on the complete quadrilateral which connect to the Newton-Gauss Line. By doing this, you can also show that several angles are equal within the complete quadrilateral. (Figure 2)

Theorem[edit]

The parallel line from ${\displaystyle E}$ to the Newton-Gauss Line of the complete quadrilateral ${\displaystyle ABCDEF}$ in addition to the line ${\displaystyle EF}$ are isogonal lines of ${\displaystyle \angle BEC}$.

Proof[edit]

Since we know from the proof conducted in the first application that triangles ${\displaystyle EDF}$ and ${\displaystyle NPM}$ are similar, we have the equality ${\displaystyle \angle DEF=\angle PNM}$. We denote the point on intersection between the side ${\displaystyle BC}$ with the parallel of ${\displaystyle NM}$ through ${\displaystyle E}$ as the point ${\displaystyle E'}$.

Because we know ${\displaystyle PN||BE}$ and ${\displaystyle NM||EE'}$, we can show that ${\displaystyle \angle BEF=\angle PNF}$, and additionally that ${\displaystyle \angle FNM=\angle E'EF}$.

Therefore, ${\displaystyle \angle CEE'=\angle DEF-\angle E'EF=\angle PNM-\angle FNM=\angle PNF=\angle BEF}$.

Two Cyclic Quadrilaterals[edit]

You are able to show that the points lying on the diagonals in combination with points that lie on the given 4 lines will form two cyclic quadrilaterals, and as a result, you are then able to prove that the two complete quadrilaterals contained within these have the same Newton-Gauss Line.

Theorem 1[edit]

Let ${\displaystyle G}$ and ${\displaystyle H}$ be the orthogonal projections of the point ${\displaystyle F}$ on the lines ${\displaystyle AB}$ and ${\displaystyle CD}$ respectively.

The quadrilaterals ${\displaystyle MPHN}$ and ${\displaystyle MQHN}$are cyclic.

Proof[edit]

From the theorem presented in the Angle Equality application, we know that ${\displaystyle \angle EFD=\angle PMN}$. The points ${\displaystyle P}$ and ${\displaystyle N}$ are the respective circumcenters of the right triangles ${\displaystyle \triangle BFG}$ and ${\displaystyle \triangle EFG}$. It then follows with the assumption that ${\displaystyle \angle PGF=\angle PFG}$ and ${\displaystyle \angle FGN=\angle GFN}$.

Therefore,

${\displaystyle {\begin{aligned}\angle PGN+\angle PMN&=(\angle PGF+\angle FGN)+\angle PMN\\&=\angle PFG+\angle GFN+\angle EFD\\&=180^{\circ }\end{aligned}}}$

Therefore, we have shown that ${\displaystyle MPGN}$ is a cyclic quadrilateral, and it's twin ${\displaystyle MQHN}$ is also cyclic by the same reasoning.

Theorem 2[edit]

Extend the lines ${\displaystyle GF}$ and ${\displaystyle HF}$ to intersect ${\displaystyle EC}$ and ${\displaystyle EB}$ at ${\displaystyle I}$ and ${\displaystyle J}$ respectively (Figure 4).

The complete quadrilaterals ${\displaystyle EFGHIJ}$ and ${\displaystyle ABCDEF}$ have the same Newton-Gauss Line.

Proof[edit]

The two complete quadrilaterals have a shared diagonal, ${\displaystyle EF}$. When each complete quadrilateral's Newton-Gauss Line is calculated, it is found that ${\displaystyle N}$ lies on the Newton-Gauss Line of both quadrilaterals. It is worth noting that ${\displaystyle N}$ is equidistant from ${\displaystyle G}$ and ${\displaystyle H}$, since it is the circumcenter of the cyclic quadrilateral ${\displaystyle EGFH}$.

We show that triangles ${\displaystyle \triangle GMP}$ and ${\displaystyle \triangle HMQ}$ are congruent, and thus it follows that ${\displaystyle M}$ lies on the perpendicular bisector of the line ${\displaystyle HG}$. Therefore, the line ${\displaystyle MN}$ contains the midpoint of ${\displaystyle GH}$, and is the Newton-Gauss Line of ${\displaystyle EFGHIJ}$.

Now for us to show that the triangles ${\displaystyle \triangle GMP}$ and and ${\displaystyle \triangle HMQ}$ are congruent, we must first note that since we have the points ${\displaystyle M}$ and ${\displaystyle P}$ being midpoints of ${\displaystyle BF}$ and ${\displaystyle BC}$ respectively, ${\displaystyle PMQF}$ is a parallelogram.

From this, we can come to the conclusion that

• ${\displaystyle MP=QF=HQ}$,
• ${\displaystyle GP=PF=MQ}$, and
• ${\displaystyle \angle MPF=\angle FQM}$.

It is important to note that ${\displaystyle \angle FPG=2\angle PBG=2\angle DBA=2\angle DCA=2\angle HCF=\angle HQF}$.

When we combine this with the third dot point above, we find:

${\displaystyle \angle MPG=\angle MPF+\angle FPG=\angle FQM+\angle HQF=\angle HQF+\angle FQM=\angle HQM}$.

Together, with the other two dot points above, this proves the congruence of triangles ${\displaystyle \triangle GMP}$ and ${\displaystyle \triangle HMQ}$.

Remark[edit]

Due to ${\displaystyle \triangle GMP}$ and ${\displaystyle \triangle HMQ}$ being congruent triangles, their circumcentres ${\displaystyle MPGN}$ and ${\displaystyle MQHN}$ are also congruent.

References[edit]

• Barbu, C. & Patrascu, I.: Some Properties of the Newton-Gauss Line
• Johnson, R.A.: Modern geometry; an elementary treatise on the geometry of the triangle and the circle.
• Bogomolny, A.: Theorem of Complete Quadrilateral
• Alperin, R.C.: Gauss-Newton Lines and Eleven Point Conics.
• Planet Math: Line Segments