prove

According to the proportional theorem of common angles , note that $\angle C = \angle C’$, there are:$\angle C=\angle C^{‘}$∠C=∠C′,Have:

$$\frac{S_{△ABC}}{S_{△A^{‘}{B}^{‘}{C}^{‘}}}=\frac{AB\cdot AC}{A^{‘}{B}^{‘}\cdot A^{‘}{C}^{‘}}=\frac{AB\cdot BC}{A^{‘}{B}^{‘}\cdot B^{‘}{C}^{‘}}=\frac{AC\cdot BC}{A^{‘}{C}^{‘}\cdot B^{‘}{C}^{‘}}$$thereby

$$\frac{AC}{A^{‘}{C}^{‘}}=\frac{BC}{B^{‘}{C}^{‘}}=\frac{AB}{A^{‘}{B}^{‘}}$$Therefore

$$△ABC△A^{‘}{B}^{‘}{C}^{‘}$$

Theorem 2

(Edge, angle, edge determination theorem) In $\triangle ABC$ and $\triangle A’B’C’$, if $\angle A = \angle A’$, and there is $\frac {AC}{A ‘C’} = \frac {AB}{A’B’}$, then $\triangle ABC \xs \triangle A’B’C’$.$△ABC$△ABCand$△A^{‘}{B}^{‘}{C}^{‘}$△A′B′C′in, if$\angle A=\angle A^{‘}$∠A=∠A′, and have$\frac{AC}{A^{‘}{C}^{‘}}=\frac{AB}{A^{‘}{B}^{‘}}$ACA′C′=ABA′B′,but$△ABC△A^{‘}{B}^{‘}{C}^{‘}$△ABC△A′B′C′.

prove

Let $\angle A$ coincide with $\angle A’$, write $\frac {AC}{A’C’} = \frac {AB}{A’B’} = k$, then by the proportional theorem of common angles (or triangle area formula) to get$\angle A$∠Aand$\angle A^{‘}$∠A′coincide, remember$\frac{AC}{A^{‘}{C}^{‘}}=\frac{AB}{A^{‘}{B}^{‘}}=k$ACA′C′=ABA′B′=k, then by

$$\frac{S_{△AB{C}^{‘}}}{S_{△ABC}}=\frac{A^{‘}{C}^{‘}}{AC}=\frac{1}{k}=\frac{A^{‘}{B}^{‘}}{AB}=\frac{S_{△AC{B}^{‘}}}{S_{△ABC}}$$thereby

$$S_{△AB{C}^{‘}}=S_{△AC{B}^{‘}}$$that is

$$S_{△BC{B}^{‘}}=S_{△BC{C}^{‘}}$$( parallel line and area relationship theorem ) then $BC \px B’C’$, then ( parallel line property theorem – theorem 3 – equal angles )$BC{B}^{‘}{C}^{‘}$BCB′C′,but

$$\angle B=\angle A{B}^{‘}{C}^{‘}=\angle B^{‘},\angle C=\angle A{C}^{‘}{B}^{‘}=\angle C^{‘}$$Therefore

$$△ABC△A^{‘}{B}^{‘}{C}^{‘}$$

Theorem 3

(Edge, edge, edge determination theorem) In $\triangle ABC$ and $\triangle A’B’C’$, if $\frac {BC}{B’C’} = \frac {AC}{A’ C’} = \frac {AB}{A’B’}$, then $\triangle ABC \xs \triangle A’B’C’$.$△ABC$△ABCand$△A^{‘}{B}^{‘}{C}^{‘}$△A′B′C′in, if$\frac{BC}{B^{‘}{C}^{‘}}=\frac{AC}{A^{‘}{C}^{‘}}=\frac{AB}{A^{‘}{B}^{‘}}$BCB′C′=ACA′C′=ABA′B′,but$△ABC△A^{‘}{B}^{‘}{C}^{‘}$△ABC△A′B′C′.

prove

Might as well set $\frac {AB}{A’B’} = k > 1$, as shown in the figure$\frac{AB}{A^{‘}{B}^{‘}}=k>1$ABA′B′=k>1, as shown in the figure

Take the point $D$ on $AB$ and the point $E$ on $AC$ so that $AD = A’B’$ and $AE = A’C’$. Judging the conditional sides, angles, and sides by the similarity of triangles $\triangle ABC \xs \triangle ADE$, thus$AB$ABtake point$D$D,exist$AC$ACtake point$E$E,Make$AD=A^{‘}{B}^{‘}$AD=A′B′,$AE=A^{‘}{C}^{‘}$AE=A′C′. Depend on$△ABC△ADE$△ABC△ADE,thus

$$\frac{BC}{DE}=\frac{AB}{AD}=\frac{AB}{A^{‘}{B}^{‘}}=k=\frac{BC}{B^{‘}{C}^{‘}}$$Thus $DE = B’C’$, ( the theorem for congruence of triangle angles ) then $\triangle A’B’C’ \qd \triangle ADE$, then $\angle A = \angle A’$, and then Use triangle similarity to determine conditional sides, angles, and sides $\angle ABC \xs \angle A’B’C’$$DE=B^{‘}{C}^{‘}$DE=B′C′,$△A^{‘}{B}^{‘}{C}^{‘}△ADE$△A′B′C′△ADE, then there are$\angle A=\angle A^{‘}$∠A=∠A′, then use$\angle ABC\angle A^{‘}{B}^{‘}{C}^{‘}$