Concept in plain English

Point \(D\) lies on side \(BC\). We’re told three segments are equal: \(BD=AD=AC\). That means:

• \(AD=AC\) ⇒ triangle \(ADC\) is isosceles with vertex at \(A\), so base angles at \(D\) and \(C\) are equal.
• \(AD=BD\) ⇒ triangle \(ABD\) is isosceles with vertex at \(D\), so base angles at \(A\) and \(B\) are equal.
• \(D\) lies on line \(BC\), so the ray \(CD\) and the ray \(CB\) are collinear (same line).

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CAT-style Question

Q. In triangle \( \triangle ABC \), a point \(D\) lies on \(BC\). If \(BD=AD=AC\) and \( \angle DAC=96^\circ\), find \( \angle C\).

Step-by-step solution (clean angle chase)

1. Work inside \( \triangle ADC\). Since \(AD=AC\), it’s isosceles with vertex angle \(\angle DAC=96^\circ\). Therefore the base angles at \(D\) and \(C\) are equal: \[ \angle ADC=\angle ACD=\frac{180^\circ-96^\circ}{2}=42^\circ. \]
2. Switch to \( \triangle ABD\). Since \(AD=BD\), base angles at \(A\) and \(B\) are equal: \[ \angle BAD=\angle ABD = x\ (\text{say}). \] The angle at \(D\) of \( \triangle ABD\) equals the angle between \(AD\) and \(DB\). Because \(DB\) is collinear with \(DC\), that angle is the supplement of \(\angle ADC\): \[ \angle ADB = 180^\circ - \angle ADC = 180^\circ - 42^\circ = 138^\circ. \] Sum of angles in \( \triangle ABD\): \(x+x+138^\circ=180^\circ \Rightarrow x=21^\circ\).
3. Find the big angle at \(A\). \(\angle BAC = \angle BAD + \angle DAC = 21^\circ + 96^\circ = 117^\circ.\)
4. Finish with triangle \(ABC\). Angles sum to \(180^\circ\): \[ \angle B + \angle C = 180^\circ - \angle A = 180^\circ - 117^\circ = 63^\circ. \] But \(\angle B\) contains \(\angle ABD = 21^\circ\) and a zero extra turn since \(DB\) and \(CB\) are the same line. Hence \(\angle B=21^\circ\). Therefore, \[ \angle C = 63^\circ - 21^\circ = \boxed{42^\circ}. \]

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Why this trick works (layman terms)