Question
QUESTION 10
10.1 In the diagram, π΅π· is the diameter of circle π΄π΅πΆπ· with centre π.
π΄ππΆ = 128Β° and π·
1 = 32Β°
Figure 10.1: Circle π΄π΅πΆπ· with centre π.
10.1.1 Calculate, with reasons, the numerical values of π· .
2
(3)
10.1.2 Calculate, with reasons, the numerical values of π΄ .
1+2
(5)
13
10.2 In the diagram, π΄π΅πΆπ· is a cyclic quadrilateral. Chords π΄πΆ and π΅π· intersect at πΉ.
π΄π· produced meets π΅πΆ produced at πΊ. πΈπ΅ is a tangent to the circle at π΅.
π΄πΆ produced cuts the tangent πΈπ΅ at πΈ. π΄πΉ = π΅πΉ, π΄ and .
1 = π¦ π΄
2 = π₯
Figure 10.2: Circle π΄π΅πΆπ·.
Express, with reasons, the size of the following in terms of π₯ and π¦:
10.2.1 π΅
1 (2)
10.2.2 π΅
2 (2)
10.2.3 π·
1 (5)
[17]
10.1 In the diagram, π΅π· is the diameter of circle π΄π΅πΆπ· with centre π.
π΄ππΆ = 128Β° and π·
1 = 32Β°
Figure 10.1: Circle π΄π΅πΆπ· with centre π.
10.1.1 Calculate, with reasons, the numerical values of π· .
2
(3)
10.1.2 Calculate, with reasons, the numerical values of π΄ .
1+2
(5)
13
10.2 In the diagram, π΄π΅πΆπ· is a cyclic quadrilateral. Chords π΄πΆ and π΅π· intersect at πΉ.
π΄π· produced meets π΅πΆ produced at πΊ. πΈπ΅ is a tangent to the circle at π΅.
π΄πΆ produced cuts the tangent πΈπ΅ at πΈ. π΄πΉ = π΅πΉ, π΄ and .
1 = π¦ π΄
2 = π₯
Figure 10.2: Circle π΄π΅πΆπ·.
Express, with reasons, the size of the following in terms of π₯ and π¦:
10.2.1 π΅
1 (2)
10.2.2 π΅
2 (2)
10.2.3 π·
1 (5)
[17]
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GPT-4o mini
To solve questions 10.1 and 10.2 based on the provided geometry and angles related to circles and cyclic quadrilaterals, letβs break down the problem into parts.
### Question 10.1
#### 10.1.1 Calculate, with reasons, the numerical values of \(D_1\).
Since \(BD\) is the diameter of the circle, angle \(BMD\) is \(90^\circ\) (angle in a semicircle).
- Given: \(AMC = 128^\circ\).
In triangle \(AMD\):
\[
\text{Angle } D = 180^\circ - AMC - BMD
\]
\[
D_1 = 180^\circ - 128^\circ - 90^\circ
\]
\[
D_1 = 180^\circ - 218^\circ = -38^\circ.
\]
Since angles cannot be negative, we must reassess \(D_1\).
We are actually calculating angle \(D_1\):
Using the cyclic nature and properties, we also know:
\[
D_1 + AMC = 180^\circ \quad (\text{angles opposite in a cyclic quadrilateral})
\]
\[
D_1 + 128^\circ = 180^\circ.
\]
\[
D_1 = 180^\circ - 128^\circ = 52^\circ.
\]
Thus:
\[
\boxed{D_1 = 52^\circ}.
\]
#### 10.1.2 Calculate, with reasons, the numerical values of \(A_1\).
Using the same cyclic quadrilateral properties:
\[
A_1 + B_1 = 180^\circ,
\]
but we know:
\[
B_1 = D_1 = 52^\circ \quad (\text{as per previous calculation}).
\]
Now we have to calculate \(A_1\):
\[
A_1 = 180^\circ - B_1.
\]
Next, we observe angle \(B\):
\[
A_1 = 180^\circ - 52^\circ = 128^\circ.
\]
Thus:
\[
\boxed{A_1 = 128^\circ}.
\]
### Question 10.2
Using the properties of cyclic quadrilaterals and tangents:
#### 10.2.1 Express \(B_1\) in terms of \(x\) and \(y\).
Since \(E\) is a point where the tangent meets the extended line \(AC\):
By the tangent-secant theorem:
\[
B_1 = y \quad \text{(angle between tangent and chord)}.
\]
Hence,
\[
\boxed{B_1 = y}.
\]
#### 10.2.2 Express \(B_2\) in terms of \(x\) and \(y\).
By the same rationale applied in \(B_2\):
- This angle is subtended by arc \(A\) opposite to it on the opposite side:
\[
B_2 = x \quad \text{(from angle subtending opposite)}.
\]
Thus:
\[
\boxed{B_2 = x}.
\]
#### 10.2.3 Express \(D_1\) in terms of \(x\) and \(y\).
In the case of \(D_1\), we apply the property of angles in opposite arcs:
\[
D_1 + y + x = 180^\circ,
\]
therefore:
\[
D_1 = 180^\circ - (x + y).
\]
Thus,
\[
\boxed{D_1 = 180^\circ - x - y}.
\]
### Summary of Results:
- \(D_1 = 52^\circ\)
- \(A_1 = 128^\circ\)
- \(B_1 = y\)
- \(B_2 = x\)
- \(D_1 = 180^\circ - x - y\)
### Question 10.1
#### 10.1.1 Calculate, with reasons, the numerical values of \(D_1\).
Since \(BD\) is the diameter of the circle, angle \(BMD\) is \(90^\circ\) (angle in a semicircle).
- Given: \(AMC = 128^\circ\).
In triangle \(AMD\):
\[
\text{Angle } D = 180^\circ - AMC - BMD
\]
\[
D_1 = 180^\circ - 128^\circ - 90^\circ
\]
\[
D_1 = 180^\circ - 218^\circ = -38^\circ.
\]
Since angles cannot be negative, we must reassess \(D_1\).
We are actually calculating angle \(D_1\):
Using the cyclic nature and properties, we also know:
\[
D_1 + AMC = 180^\circ \quad (\text{angles opposite in a cyclic quadrilateral})
\]
\[
D_1 + 128^\circ = 180^\circ.
\]
\[
D_1 = 180^\circ - 128^\circ = 52^\circ.
\]
Thus:
\[
\boxed{D_1 = 52^\circ}.
\]
#### 10.1.2 Calculate, with reasons, the numerical values of \(A_1\).
Using the same cyclic quadrilateral properties:
\[
A_1 + B_1 = 180^\circ,
\]
but we know:
\[
B_1 = D_1 = 52^\circ \quad (\text{as per previous calculation}).
\]
Now we have to calculate \(A_1\):
\[
A_1 = 180^\circ - B_1.
\]
Next, we observe angle \(B\):
\[
A_1 = 180^\circ - 52^\circ = 128^\circ.
\]
Thus:
\[
\boxed{A_1 = 128^\circ}.
\]
### Question 10.2
Using the properties of cyclic quadrilaterals and tangents:
#### 10.2.1 Express \(B_1\) in terms of \(x\) and \(y\).
Since \(E\) is a point where the tangent meets the extended line \(AC\):
By the tangent-secant theorem:
\[
B_1 = y \quad \text{(angle between tangent and chord)}.
\]
Hence,
\[
\boxed{B_1 = y}.
\]
#### 10.2.2 Express \(B_2\) in terms of \(x\) and \(y\).
By the same rationale applied in \(B_2\):
- This angle is subtended by arc \(A\) opposite to it on the opposite side:
\[
B_2 = x \quad \text{(from angle subtending opposite)}.
\]
Thus:
\[
\boxed{B_2 = x}.
\]
#### 10.2.3 Express \(D_1\) in terms of \(x\) and \(y\).
In the case of \(D_1\), we apply the property of angles in opposite arcs:
\[
D_1 + y + x = 180^\circ,
\]
therefore:
\[
D_1 = 180^\circ - (x + y).
\]
Thus,
\[
\boxed{D_1 = 180^\circ - x - y}.
\]
### Summary of Results:
- \(D_1 = 52^\circ\)
- \(A_1 = 128^\circ\)
- \(B_1 = y\)
- \(B_2 = x\)
- \(D_1 = 180^\circ - x - y\)
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