Determinants

Let M_ij and C_ij represents the minor and co–factor of an element, where i and j represent the row and column.

The minor of the matrix can be obtained for a particular element by removing the row and column where the element is present. Then finding the absolute value of the matrix newly formed.

Also, C_ij = (–1)^i+j × M_ij

M₁₁ = –1

M₂₁ = 20

C₁₁ = (–1)¹⁺¹ × M₁₁

= 1 × –1

= –1

C₂₁ = (–1)²⁺¹ × M₂₁

= 20 × –1

= –20

Now expanding along the first column we get

|A| = a₁₁ × C₁₁ + a₂₁× C₂₁

= 5× (–1) + 0 × (–20)

= –5

Let M_ij and C_ij represents the minor and co–factor of an element, where i and j represent the row and column.

The minor of matrix can be obtained for particular element by removing the row and column where the element is present. Then finding the absolute value of the matrix newly formed.

Also, C_ij = (–1)^i+j × M_ij

M₁₁ = 3

M₂₁ = 4

C₁₁ = (–1)¹⁺¹ × M₁₁

= 1 × 3

= 3

C₂₁ = (–1)²⁺¹ × 4

= –1 × 4

= –4

Now expanding along the first column we get

|A| = a₁₁ × C₁₁ + a₂₁× C₂₁

= –1× 3 + 2 × (–4)

= –11

Let M_ij and C_ij represents the minor and co–factor of an element, where i and j represent the row and column.

The minor of the matrix can be obtained for a particular element by removing the row and column where the element is present. Then finding the absolute value of the matrix newly formed.

Also, C_ij = (–1)^i+j × M_ij

M₁₁ = –1×2 – 5×2

M₁₁ = –12

M₂₁ = –3×2 – 5×2

M₂₁ = –16

M₃₁ = –3×2 – (–1) × 2

M₃₁ = –4

C₁₁ = (–1)¹⁺¹ × M₁₁

= 1 × –12

= –12

C₂₁ = (–1)²⁺¹ × M₂₁

= –1 × –16

= 16

C₃₁ = (–1)³⁺¹ × M₃₁

= 1 × –4

= –4

Now expanding along the first column we get

|A| = a₁₁ × C₁₁ + a₂₁× C₂₁+ a₃₁× C₃₁

= 1× (–12) + 4 × 16 + 3× (–4)

= –12 + 64 –12

= 40

Let M_ij and C_ij represents the minor and co–factor of an element, where i and j represent the row and column.

The minor of the matrix can be obtained for a particular element by removing the row and column where the element is present. Then finding the absolute value of the matrix newly formed.

Also, C_ij = (–1)^i+j × M_ij

M₁₁ = b × ab – c × ca

M₁₁ = ab² – ac²

M₂₁ = a × ab – c × bc

M₂₁ = a²b – c²b

M₃₁ = a × ca – b × bc

M₃₁ = a²c – b²c

C₁₁ = (–1)¹⁺¹ × M₁₁

= 1 × (ab² – ac²)

= ab² – ac²

C₂₁ = (–1)²⁺¹ × M₂₁

= –1 × (a²b – c²b)

= c²b – a²b

C₃₁ = (–1)³⁺¹ × M₃₁

= 1 × (a²c – b²c)

= a²c – b²c

Now expanding along the first column we get

|A| = a₁₁ × C₁₁ + a₂₁× C₂₁+ a₃₁× C₃₁

= 1× (ab² – ac²) + 1 × (c²b – a²b) + 1× (a²c – b²c)

= ab² – ac² + c²b – a²b + a²c – b²c

Let M_ij and C_ij represents the minor and co–factor of an element, where i and j represent the row and column.

The minor of matrix can be obtained for particular element by removing the row and column where the element is present. Then finding the absolute value of the matrix newly formed.

Also, C_ij = (–1)^i+j × M_ij

M₁₁ = 5×1 – 7×0

M₁₁ = 5

M₂₁ = 2×1 – 7×6

M₂₁ = –40

M₃₁ = 2×0 – 5×6

M₃₁ = –30

C₁₁ = (–1)¹⁺¹ × M₁₁

= 1 × 5

= 5

C₂₁ = (–1)²⁺¹ × M₂₁

= –1 × –40

= 40

C₃₁ = (–1)³⁺¹ × M₃₁

= 1 × –30

= –30

Now expanding along the first column we get

|A| = a₁₁ × C₁₁ + a₂₁× C₂₁+ a₃₁× C₃₁

= 0× 5 + 1 × 40 + 3× (–30)

= 0 + 40 – 90

= 50

Let M_ij and C_ij represents the minor and co–factor of an element, where i and j represent the row and column.

The minor of matrix can be obtained for particular element by removing the row and column where the element is present. Then finding the absolute value of the matrix newly formed.

Also, C_ij = (–1)^i+j × M_ij

M₁₁ = b × c – f × f

M₁₁ = bc– f²

M₂₁ = h × c – f × g

M₂₁ = hc – fg

M₃₁ = h × f – b × g

M₃₁ = hf – bg

C₁₁ = (–1)¹⁺¹ × M₁₁

= 1 × (bc– f²)

= bc– f²

C₂₁ = (–1)²⁺¹ × M₂₁

= –1 × (hc – fg)

= fg – hc

C₃₁ = (–1)³⁺¹ × M₃₁

= 1 × (hf – bg)

= hf – bg

Now expanding along the first column we get

|A| = a₁₁ × C₁₁ + a₂₁× C₂₁+ a₃₁× C₃₁

= a× (bc– f²) + h× (fg – hc) + g× (hf – bg)

= abc– af² + hgf – h²c +ghf – bg²

Let M_ij and C_ij represents the minor and co–factor of an element, where i and j represent the row and column.

The minor of matrix can be obtained for particular element by removing the row and column where the element is present. Then finding the absolute value of the matrix newly formed.

Also, C_ij = (–1)^i+j × M_ij

M₁₁ = 0(–1×0 – 5×1) – 1(1×0 – (–1)×1) + (–2)(1×5 – (–1)×(–1))

M₁₁ = – 9

M₂₁ = –1(–1×0 – 5×1) – 0(1×0 – (–1)×1) + 1(1×5 – (–1)×(–1))

M₂₁ = 9

M₃₁ = –1(1×0 – 5×(–2)) – 0(0×0 – (–1)×(–2)) + 1(0×5 – (–1)×1)

M₃₁ = –9

M₄₁ = –1(1×1 – (–1)×(–2)) – 0(0×1 – 1×(–2)) + 1(0×(–1) – 1×1)

M₄₁ = 0

C₁₁ = (–1)¹⁺¹ × M₁₁

= 1 × (–9)

= –9

C₂₁ = (–1)²⁺¹ × M₂₁

= –1 × 9

= –9

C₃₁ = (–1)³⁺¹ × M₃₁

= 1 × –9

= –9

C₄₁ = (–1)⁴⁺¹ × M₄₁

= –1 × 0

= 0

Now expanding along the first column we get

|A| = a₁₁ × C₁₁ + a₂₁× C₂₁+ a₃₁× C₃₁ + a₄₁× C₄₁

= 2× (–9) + (–3) × –9 + 1× (–9) + 2× 0

= – 18 + 27 –9

= 0

I.

⇒ |A| = x(5x + 1) – (–7)x

|A| = 5x² + 8x

II.

⇒ |A| = cosθ × cosθ – (–sinθ) x sinθ

|A| = cos²θ + sin²θ

|A| = 1

III.

⇒ |A| = cos15° × cos75° + sin15° x sin75°

|A| = cos(75 – 15)°

|A| = cos60°

|A| = 0.5.

IV.

⇒ |A| = (a + ib)( a – ib) – (c + id)( –c + id)

= (a + ib)( a – ib) + (c + id)( c – id)

= a² – i² b² + c² – i² d²

= a² – (–1)b² + c² – (–1)d²

= a² + b² + c² + d²

Since |AB|= |A||B|

= 2(17×12 – 5×20) – 3(13×12 – 5×15) + 7(13×20 – 15×17)

= 2(204 – 100) – 3(156 – 75) + 7(260 – 255)

= 2×104 – 3×81 + 7×5

= 208 – 243 +35

= 0

Now |A|² = |A|×|A|

|A|²= 0

Using sin(A+B) = sinA × cosB + cosA × sinB

⇒ |A| = sin10° × cos80° + cos10° x sin80°

|A| = sin(10 + 80)°

|A| = sin90°

|A| = 1

Hence Proved

I. Expanding along the first row

= 2(1×1 – 4×(–2)) – 3(7×1 – (–2)×(–3)) – 5(7×4 – 1×(–3))

= 2(1 + 8) – 3(7 – 6) – 5(28 + 3)

= 2×9 – 3×1 – 5×31

= 18 – 3 – 155

= –140

II. Expanding along the second column

= 2(1×1 – 4×(–2)) – 7(3×1 – 4×(–5)) – 3(3×(–2) – 1×(–5))

= 2(1 + 8) – 7(3 + 20) – 3(–6 + 5)

= 2×9 – 7×23 – 3×(–1)

= 18 – 161 +3

= –140

Expanding along the first row

⇒ |A| = 0(0 – sinβ(–sinβ) ) –sinα(–sinα× 0 – sinβ cosα ) – cosα((–sinα)(–sinβ) – 0× cosα )

|A| = 0 + sinα sinβ cosα – cosα sinα sinβ

|A| = 0

Expanding along the second row

⇒ |A| = sinβ (cosα×cosα sinβ + sinα × sinα sinβ) + cosβ (cosα cosβ × cosα + sinα×sinα cosβ) – 0

|A| = sin² β (cos²α + sin²α) + cos²β (cos²α + sin²α)

|A| = sin² β (1) + cos²β (1)

|A| = sin² β + cos²β

|A| = 1

Now |A|= 2 × 1 – 2 × 5

|A|= 2 – 10

|A|= –8

Now |B|= 4 × 5 – 2 × (–3)

|B|= 20 + 6

|B|= 26

⇒ |A|×|B|= –8 × 26

|A|×|B|= –208

Now

|AB| = 18 × (–1) – 19 × 10

|AB| = –18 – 190

|AB| = –208

Hence |AB| =|A|×|B|.

Expanding along the first row

= 1(1×4 – 2×0) – 0(0×4 – 0×2) + 1(0×0 – 0×1)

= 1(4 – 0) + 0 + 1(0 + 0)

= 1×4

= 4

Now

Expanding along the first row

= 3(3×12 – 6×0) – 0(0×12 – 0×6) + 3(0×0 – 0×3)

= 3(36 – 0) + 0 + 3(0 + 0)

= 3×36

= 108

= 27 × 4

= 27 |A|

Hence, |3A|= 27 |A|

⇒ 2 × 1 – 4 × 5 = 2x × x – 4 × 6

⇒ 2 – 20 = 2x² – 24

⇒ 2x² = –18 +24

⇒ 2x² = 6

⇒ x² = 3

⇒ x = ±√ 3

⇒ 2 × 5 – 4 × 3 = x × 5 – 2x × 3

⇒ 10 – 12 = 5x – 6x

⇒ –x = –2

⇒ x = 2

⇒ 3 × 1 – x × x = 3 × 1 – 4 × 2

⇒ 3 – x² = 3 – 8

⇒ – x² = –5 –3

⇒ –x² = –8

⇒ x = ±2√ 2

⇒ 3x × 4 – 7 × 2 = 10

⇒ 12x – 14 = 10

⇒ 12x= 10 +14

⇒ 12x = 24

⇒ x = 2

⇒ (x+1)(x+2) – (x–1)(x–3) = 4 × 3 – 1 × (–1)

⇒ (x² + 2x + x + 2) – (x² – 3x – x + 3) = 12 + 1

⇒ –2x –1= 13

⇒ –2x = 14

⇒ x = –7

⇒ 2x × x – 5 × 8 = 6 × 3 – 5 × 8

⇒ 2x² – 40 = 18 – 40

⇒ 2x² = 18

⇒ x² = 9

⇒ x = ±3

Expanding along the first row

= x²(2×4 – 1×1) – x(0×4 – 1×3) + 1(0×1 – 2×3)

= x²(8 – 1) – x(0 – 3) + 1(0 – 6)

= 7x² + 3x –6

Also |A| = 28

⇒ 7x² + 3x – 6 =28

⇒ 7x² + 3x – 34 = 0

⇒ 7x² + 17x – 14x – 34 = 0

⇒ x(7x+ 17) – 2(7x +17) = 0

⇒ (x–2)(7x +17) = 0

Integer value of x is 2.

⇒ (1 + x) × 8 – 7 × (3 – x) = 0

⇒ 8 + 8x – 21 + 7x = 0

⇒ 15x – 13 = 0

Expanding along the first row

= (x–1) ((x–1) (x–1)– 1×1) – 1((x–1) – 1×1) + 1(1×1 – 1×(x–1))

= (x–1) (x² – 2x + 1 – 1) – 1(x–1 – 1) + 1(1 – x+1)

= x(x–1) (x– 2) – 1(x–2) – (x–2)

= (x– 2) {x(x–1) – 1 – 1}

= (x– 2) (x² – x – 2)

For singular |A| = 0,

(x– 2) (x² – x – 2) = 0

(x– 2) (x² – 2x + x – 2) = 0

(x–2)(x–2)(x+1) = 0

∴ x = –1 or 2

Also |A| = 28

⇒ 7x² + 3x – 6 =28

⇒ 7x² + 3x – 34 = 0

⇒ 7x² + 17x – 14x – 34 = 0

⇒ x(7x+ 17) – 2(7x +17) = 0

⇒ (x–2)(7x +17) = 0

Applying, R₂→ R₂ – R₁, we get,

So,

Applying, C₁ → C₁ – 4 C₃, we get,

Applying, R₁ → R₁ + R₂ and R₃→ R₃ – R₂, we get

Now, applying R₂ → R₂ + 3 R₁, we get,

= 1[(109)(12) – (119)(11)] = 1308 – 1309

= – 1

So, Δ = – 1

= a(bc – f²) – h(hc – fg) + g(hf – bg)

= abc – af² – ch² + fgh + fgh – bg²

= abc + 2fgh – af² – bg² – ch²

So, Δ = abc + 2fgh – af² – bg² – ch²

Applying, R₂ → R₂ – R₁ and R₃ → R₃ – R_1, we get

= 2[1(24 – 4)] = 40

So, Δ = 40

Applying C₃→ C₃ – C₂, we get,

Applying C₂ → C₂ + C₁, we get,

Applying C₂→ C₂ – 5C₁ and C₃ →C₃ – 5C₁ we get,

= 1[( – 7)( – 36) – ( – 20)( – 13)] = 252 – 260

= – 8

So, Δ = – 8

Applying, R₁ → R₁ – 3R₂ and R₃ → R₃ + 5R₂ we get,

So, Δ = 0

Applying C₁ → C₁ + C₂ + C₃ + C₄, we get,

Now, applying R₂ → R₂ – R₁, R₃ → R₃ – R₁, R₄ → R₄ – R₁, we get

Now, applying R₁ → R₁ + 3R₃

= (40)(8)(40)(40) = 512000

So, Δ = 512000

Applying R₃ → R₃ – R₁, we get,

So, Δ = 0

Applying R₃ → R₃ – R₂, we get

Applying R₂ → R₂ – R₁, we get

As, R₂ = R₃, therefore the value of the determinant is zero.

Taking ( – 2) common from C₁ we get,

As, C₁ = C₂, hence the value of the determinant is zero.

Applying C₃ → C₃ – C₂, gives

As, R₁ = R₃, so value so determinant is zero.

Multiplying R₁, R₂ and R₃ with a, b and c respectively we get,

Taking, abc common from C₃ gives,

As, C₁ = C₃ hence value of determinant is zero.

Applying C₃ → C₃ – C₂, we get,

Applying C₂→C₂ – C₁ gives,

As, C₂ = C₃, so the value of the determinant is zero.

Applying R₂→R₂ – R₁ and R₃ → R₃ – R₁, we get,

Taking (b – a) and (c – a) common from R₂ and R₃ respectively,

= [(b – a)(c – a)][(c + a) – (b + a) – ( – b + c)]

= [(b – a)(c – a)][c + a + b – a – b – c]

= [(b – a)(c – a)][0] = 0

Applying, C₁→C₁ – 8C₃

As, C₁ = C₂ hence, the determinant is zero.

Multiplying C₁, C₂ and C₃ with z, y and x respectively we get,

Now, taking y, x and z common from R₁, R₂ and R₃ gives,

Applying C₂ → C₂ – C₃ gives,

As, C₁ = C₂, therefore determinant is zero.

Applying C₂→C₂ – 7C₃, we get

As, C₁ = C₂, hence determinant is zero.

Applying C₃→C₃ – C₂, and C₄→C₄ – C₁

Taking 3 common from C₄ we get,

As, C3 = C4 so, the determinant is zero.

Applying, C₂→C₂ + C₁ and C₃→C₃ + C₁

Taking 2 common from R₂ we get,

As, R₂ = R₃, hence value of determinant is zero.

Applying, C₁→C₁ – C₂, we get

As C₁ = C₃ hence determinant is zero.

Multiplying C₁ with sin δ, C₂ with cos δ, we get

Now, applying, C₂→C₂ – C₁, we get,

As C₂ = C₃ hence determinant is zero.

Applying C₁→C₁ + C₂, we get

Using, sin(90 – A) = cos A, sin² A + cos² A = 1 ,and cos 180˚ = – 1,

Taking, ( – 1) common from C₁, we get

Therefore, as C₁ = C₃ determinant is zero.

Multiplying R₂ with sin y and R₃ with cos y we get,

Now, applying R₂→R₂ + R₃, we get,

Taking ( – 1) common from R₂, we get

As R₁ = R₂ hence determinant is zero.

Multiplying C₂ with and C₃ with we get,

Taking common from C₂ and C₃ we get,

Applying C₂→C₂ + C₃

As C₁ = C₂ hence determinant is zero.

Now,

Δ = sin² A (cot B – cot C) – cot A (sin² B – sin² C) + 1 (sin²B cot C – cot B sin² C

As A, B and C are angles of a triangle,

A + B + C = 180°

Δ = sin² A cot B – sin² A cot C – cot A sin² B + cot A sin²C + sin²B cot C – cot B sin² C

By using formulae,

Δ = 0

Hence, Proved.

Applying, C₂→C₂ + C₁

Taking, (a + b + c) common,

Applying R₂→R₂ – R₁, and R₃→R₃ – R₁

Taking, (b – c) and (c – a) common,

= (a + b + c)(b – a)(c – a)(b – c)

So, Δ = (a + b + c)(b – a)(c – a)(b – c)

Applying, R₂→R₂ – R₁ and R₃→R₃ – R₁ we get,

Taking (a – b) and (a – c) common we get,

= (a – b)(c – a)(b – c)

So, Δ = (a – b)(b – c)(c – a)

Applying, C₁→C₁ + C₂ + C₃, we have,

Taking, (3x + λ) common, we get

Applying, R₂→R₂ – R₁, R₃→R₃ – R₁, we get,

= λ²(3x + λ)

So, Δ = λ²(3x + λ)

Applying, C₁→C₁ + C₂ + C₃, we get,

Taking, (a + b + c) we get,

Applying, R₂→R₂ – R₁, R₃→R₃ – R₁, we get,

= (a + b + c)[(a – b)(a – c) – (b – c)(c – b)]

= (a + b + c)[a² – ac – ab + bc + b² + c² – 2bc]

= (a + b + c)[a² + b² + c² – ac – ab – bc]

So, Δ = (a + b + c)[a² + b² + c² – ac – ab – bc]

Applying, C₁→C₁ + C₂ + C₃, we get,

Applying, R₂→R₂ – R₁, R₃→R₃ – R₁, we get,

= (2 + x)(x – 1)²

So, Δ = (2 + x)(x – 1)²

= 0(0 – y³z³) – xy²(0 – x²yz³) + xz²(x²y³z – 0)

= 0 + x³y³z³ + x³y³z³

= 2x³y³z³

So, Δ = 2x³y³z³

Applying R₁→R₁ – R₂ and R₃→R₃ – R₂

Applying, C₂→C₂ – C₁

= a[a(a + x + y) + az] + 0 + 0

= a²(a + x + y + z)

So, Δ = a²(a + x + y + z)

As |A| = |A|^T

If any two rows or columns of the determinant are interchanged, then determinant changes its sign

So, Δ = 0

L.H.S =

Apply C₁→C₁ + C₂ + C₃

Taking (a + b + c) common from C₁ we get,

Applying, R₃→R₃ – 2R₁

= (a + b + c)[(b – c)(a + b – 2c) – (c – a)(c + a – 2b)]

= a³ + b³ + c³ – 3abc

As, L.H.S = R.H.S

Hence, proved.

L.H.S =

As |A| = |A|^T

So,

If any two rows or columns of the determinant are interchanged, then determinant changes its sign

Apply C₁→C₁ + C₂ + C₃

Taking (a + b + c) common from C₁ we get,

Applying, R₃→R₃ – 2R₁

= – (a + b + c)[(b – c)(a + b – 2c) – (c – a)(c + a – 2b)]

= 3abc – a³ – b³ – c³

As, L.H.S = R.H.S, hence proved.

L.H.S =

Applying, C₁→C₁ + C₂ + C₃

Apply, C₂→C₂ – C₁, and C₃→C₃ – C₁, we have

Hence, proved.

,

R.H.S = 2(a + b + c)²

Applying C₁→C₁ + C₂ + C₃, we have

Taking, 2(a + b + c) common we get,

Now, applying R₂→R₂ – R₁ and R₃→R₃ – R₁, we get,

Thus, we have

L.H.S = 2(a + b + c)[1(a + b + c)²]

= 2(a + b + c)³ = R.H.S

Hence, proved.

L.H.S =

Applying, R₁→R₁ + R₂ + R₃, we get,

Taking (a + b + c) common we get,

Applying C₂→C₂ – C₁ and C₃→C₃ – C₁, we get,

= (a + b + c)³ = R.H.S

Hence, proved.

Applying, R₂→R₂ – R₁ and R₃→R₃ – R₁, we get,

Applying R₃→R₃ – R₂, we get,

= (a – b)(a – c)(b – c) = R.H.S

Hence, proved.

Applying R₁→R₁ + R₂ + R₃, we get,

Taking, (3a + 2b) common we get,

Applying, C₁→C₁ – C₂ and C₃→C₃ – C₂, we get,

= 3(a + b)b²(3) = 9(a + b) b²

= R.H.S

Hence, proved.

Applying, R₁→a R₁, R₂→b R₂, R₃→c R₃

Hence, proved.

= – xyz(x – y)(z – y)[z² + y² + zy – x² – y² – xy]

= – xyz(x – y)(z – y)[(z – x)(z + x0 + y(z – x)]

= – xyz(x – y)(z – y)(z – x)(x + y + z)

= R.H.S

Hence, proved.

Applying, C₁→C₁ + C₂ – 2C₃

Taking (a² + b² + c²), common, we get,

Applying R₂→R₂ – R₁ and R₃→R₃ – R₁, we get,

= (a² + b² + c²)(b – a)(c – a)[(b + a)( – b) – ( – c)(c + a)]

= (a² + b² + c²)(a – b)(c – a)(b – c)(a + b + c)

= R.H.S

Hence, proved.

Applying, R₃→R₃ – R₂

Applying, R₂→R₂ – R₁

= [(2a + 4)(1) – (1)(2a + 6)]

= – 2

= R.H.S

Hence, proved.

Applying, C₂→C₂ – 2C₁ – 2C₃, we get,

Taking, – (a² + b² + c²) common from C₂ we get,

Applying R₂→R₂ – R₁ and R₃→R₃ – R₁, we get

= – (a² + b² + c²)(a – b)(c – a)[( – (b + a))( – b) – (c)(c + a)]

= (a – b)(b – c)(c – a)(a + b + c)(a² + b² + c²)

= R.H.S

Hence, proved.

Applying, R₂→R₂ – R₁, and R₃→R₃ – R₁

= (b – a)(c – a)[((b + a – c))(c² + a² + ac) – (b² + a² + ab)(c² + a² + ac)]

= – (a – b)(c – a)(b – c)(a² + b² + c²)

= R.H.S

Hence, proved.

Taking, a,b,c common from C₁, C₂, C₃ respectively we get,

Applying, C₁→C₁ + C₂ + C₃, we get,

Applying, C₂→C₂ – C₁ and C₃→C₃ – C₁, we get,

Applying, C₁→C₁ + C₂ + C₃, we get,

Taking c, a, b common from C₁, C₂, C₃ respectively, we get,

Applying, R₃→R₃ – R₁, we have

= 2a²b²c²(2)

= 4a²b²c² = R.H.S

Hence, proved.

Applying, C₁→C₁ + C₂ + C₃, we get,

Taking (3x + 4) common we get,

Applying, R₂→R₂ – R₁ and R₃→R₃ – R₁, we get,

= 16(3x + 4)

Hence proved.

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying C₂→ C₂ – pC₁, we get

Applying C₃→ C₃ – qC₁, we get

Applying C₃→ C₃ – pC₂, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = 1[(1)(7) – (3)(2)] – 0 + 0

∴ Δ = 7 – 6 = 1

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ – R₂, we get

Applying R₁→ R₁ – R₃, we get

Taking the term (a – b – c) common from R₁, we get

Applying C₂→ C₂ + C₁, we get

Applying C₃→ C₃ + C₁, we get

Expanding the determinant along R₁, we have

Δ = (a – b – c)[–1(b + a – c)(c + a – b) – 0 + 0]

⇒ Δ = –(a – b – c)(b + a – c)(c + a – b)

∴ Δ = (b + c – a)(a + b – c)(c + a – b)

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Taking the term (a² + b² + 2ab) common from R₁, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = (a + b)² [(a² – b²)(a² – 2ab) – (b² – 2ab)(2ab – b²)]

⇒ Δ = (a + b)² [a⁴ – 2a³b – b²a² + 2ab³ – 2ab³ + b⁴ + 4a²b² – 2ab³]

⇒ Δ = (a + b)² [a⁴ – 2a³b + 3a²b² – 2ab³ + b⁴]

⇒ Δ = (a + b)² [a⁴ + b⁴ + 2a²b² – 2a³b – 2ab³ + a²b²]

⇒ Δ = (a + b)² [(a² + b²)² – 2ab(a² + b²) + (ab)²]

⇒ Δ = (a + b)² [(a² + b² – ab)²]

⇒ Δ = [(a + b)(a² + b² – ab)]²

∴ Δ = (a³ + b³)²

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Taking the term (a² + a + 1) common from R₁, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = (a² + a + 1)(1)[(1 – a²)(1 – a) – (a² – a)(a – a²)]

⇒ Δ = (a² + a + 1)(1 – a – a² + a³ – a³ + a⁴ + a² – a³)

⇒ Δ = (a² + a + 1)(1 – a – a³ + a⁴)

⇒ Δ = (a² + a + 1)(a⁴ – a³ – a + 1)

⇒ Δ = (a² + a + 1)[a³(a – 1) – (a – 1)]

⇒ Δ = (a² + a + 1)(a – 1)(a³ – 1)

⇒ Δ = (a – 1)(a² + a + 1)(a³ – 1)

⇒ Δ = (a³ – 1)(a³ – 1)

∴ Δ = (a³ – 1)²

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Applying C₂→ C₂ + C₁, we get

Applying C₃→ C₃ + C₁, we get

Taking (a + b) and (c + a) common from C₂ and C₃, we get

Applying R₂→ R₂ + R₁, we get

Applying R₃→ R₃ – R₁, we get

Expanding the determinant along C₃, we have

Δ = (a + b)(c + a)[(–c + a)(–2) – (–b – a)(2)]

⇒ Δ = (a + b)(c + a)[2c – 2a + 2a + 2b]

⇒ Δ = (a + b)(c + a)(2b + 2c)

∴ Δ = 2(a + b)(b + c)(c + a)

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ – R₂, we get

Applying R₁→ R₁ – R₃, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

⇒ Δ = 0 + (2c)[(b)(a + b – c)] + (–2b)[–(c)(c + a – b)]

⇒ Δ = 2bc(a + b – c) + 2bc(c + a – b)

⇒ Δ = 2bc[(a + b – c) + (c + a – b)]

⇒ Δ = 2bc[2a]

∴ Δ = 4abc

Thus,

Let

Multiplying a, b and c to R₁, R₂ and R₃, we get

Dividing C₁, C₂ and C₃ with a, b and c, we get

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ – R₂, we get

Applying R₁→ R₁ – R₃, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = 0 + (2c²)[(b²)(a² + b² – c²)] + (–2b²)[–(c²)(c² + a² – b²)]

⇒ Δ = 2b²c²(a² + b² – c²) + 2b²c²(c² + a² – b²)

⇒ Δ = 2b²c² [(a² + b² – c²) + (c² + a² – b²)]

⇒ Δ = 2b²c²[2a²]

∴ Δ = 4a²b²c²

Thus,

Let

Taking a², b² and c² common from C₁, C₂ and C₃, we get

Taking a, b and c common from R₁, R₂ and R₃, we get

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying C₂→ C₂ – C₃, we get

Expanding the determinant along R₁, we have

Δ = (a³b³c³)[0 – 0 + 1(1)(1) – (1)(–1)]

⇒ Δ = (a³b³c³)[1 + 1]

∴ Δ = 2a³b³c³

Thus,

Let

Multiplying c, a and b to R₁, R₂ and R₃, we get

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ – R₂, we get

Applying R₁→ R₁ – R₃, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

∴ Δ = 4abc

Thus,

Let

Multiplying a, b and c to R₁, R₂ and R₃, we get

Dividing C₁, C₂ and C₃ with a, b and c, we get

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Taking the term (a – b – c) common from R₁, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = (ab + bc + ca)(1)[(ab + bc + ca)(ab + bc + ca)]

∴ Δ = (ab + bc + ca)³

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Taking the term (5x + λ) common from R₁, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = (5x + λ)[(1)(λ – x)(λ – x)]

∴ Δ = (5x + λ)(λ – x)²

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Taking the term (5x + 4) common from R₁, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = (5x + 4)[(1)(4 – x)(4 – x)]

∴ Δ = (5x + 4)(4 – x)²

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ – R₂, we get

Applying R₁→ R₁ – R₃, we get

Taking the term (–2x) common from R₁, we get

Applying C₂→ C₂ – C₃, we get

Expanding the determinant along R₁, we have

Δ = (–2x)[(z)(–y) – (y)(z)]

⇒ Δ = (–2x)(–yz –yz)

⇒ Δ = (–2x)(–2yz)

∴ Δ = 4xyz

Thus,

Let

Taking a, b and c common from C₁, C₂ and C₃, we get

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ – R₂, we get

Taking the term (a² + b² + c²) common from R₁, we get

Applying R₂→ R₂ – R₃, we get

Taking the term (a² + b² + c²) common from R₂, we get

Applying C₂→ C₂ + C₁, we get

Expanding the determinant along R₁, we have

Δ = (abc)(a² + b² + c²)²(–1)[(a² + b² – c²) – (2b² + 2a²)]

⇒ Δ = (abc)(a² + b² + c²)²[–(a² + b² – c²) + (2b² + 2a²)]

⇒ Δ = (abc)(a² + b² + c²)²[–a² – b² + c² + 2b² + 2a²]

⇒ Δ = (abc)(a² + b² + c²)²[a² + b² + c²]

∴ Δ = (abc)(a² + b² + c²)³

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Taking the term (3 + a) common from R₁, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = (3 + a)(1)[(a)(a) – 0]

⇒ Δ = (3 + a)(a²)

∴ Δ = a³ + 3a²

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Taking the term (x + y + z) common from R₁, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = (x + y + z)(1)[0 – (–(x + y + z)(x + y + z))]

⇒ Δ = (x + y + z)(x + y + z)(x + y + z)

∴ Δ = (x + y + z)³

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Taking the term (x + y + z) common from R₁, we get

Applying C₁→ C₁ – C₂, we get

Applying C₁→ C₁ – C₃, we get

Expanding the determinant along C₁, we have

Δ = (x + y + z)(x – z)[(1)(x) – (z)(1)]

⇒ Δ = (x + y + z)(x – z)(x – z)

∴ Δ = (x + y + z)(x – z)²

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying C₁→ C₁ + C₂, we get

Applying C₁→ C₁ + C₃, we get

Taking the term (a + x + y + z) common from C₁, we get

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

Expanding the determinant along C₁, we have

Δ = (a + x + y + z)(1)[(a)(a) – (0)(0)]

⇒ Δ = (a + x + y + z)(a)(a)

∴ Δ = a²(a + x + y + z)

Thus,

Let

Taking 2 common from C₂, we get

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

We have the identity a³ – b³ = (a – b)(a² + ab + b²)

Taking (b – a) and (c – a) common from R₂ and R₃, we get

We know that the sign of a determinant changes if any two rows or columns are interchanged.

By interchanging C₁ and C₂, we get

Expanding the determinant along C₁, we have

Δ = –2(b – a)(c – a)(1)[(b² + ba + a²) – (c² + ca + a²)]

⇒ Δ = 2(a – b)(c – a)[b² + ba + a² – c² – ca – a²]

⇒ Δ = 2(a – b)(c – a)[b² + ba – c² – ca]

⇒ Δ = 2(a – b)(c – a)[b² – c² + (ba – ca)]

⇒ Δ = 2(a – b)(c – a)[(b – c)(b + c) + (b – c)a]

⇒ Δ = 2(a – b)(c – a)(b – c)(b + c + a)

∴ Δ = 2(a – b)(b – c)(c – a)(a + b + c)

Thus,

Let

We know that the sign of a determinant changes if any two rows or columns are interchanged.

By interchanging R₁ and R₂, we get

By interchanging R₂ and R₃, we get

Hence,

Let us once again consider

By interchanging R₁ and R₂, we get

By interchanging C₁ and C₂, we get

Recall that the value of a determinant remains same if it its rows and columns are interchanged.

Hence,

Thus,

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₃, we get

Given that a, b and c are in an A.P. Using the definition of an arithmetic progression, we have

b – a = c – b

⇒ b + b = c + a

⇒ 2b = c + a

∴ a + c = 2b

By substituting this in the above equation to find Δ, we get

Taking 2 common from R₁, we get

Applying R₁→ R₁ – R₂, we get

∴ Δ = 0

Thus, when a, b and c are in A.P.

Let

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₃, we get

Given that α, β and γ are in an A.P. Using the definition of an arithmetic progression, we have

β – α = γ – β

⇒ β + β = γ + α

⇒ 2β = γ + α

∴ α + γ = 2β

By substituting this in the above equation to find Δ, we get

Taking 2 common from R₁, we get

Applying R₁→ R₁ – R₂, we get

∴ Δ = 0

Thus, when α, β and γ are in A.P.

Let

Given that Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ + R₂, we get

Applying R₁→ R₁ + R₃, we get

Taking the term 2(a + b + c) common from R₁, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₁, we have

Δ = 2(a + b + c)(1)[(b – c)(c – b) – (c – a)(b – a)]

⇒ Δ = 2(a + b + c)(bc – b² – c² + cb – cb + ca + ab – a²)

∴ Δ = 2(a + b + c)(ab + bc + ca – a² – b² – c²)

We have Δ = 0

⇒ 2(a + b + c)(ab + bc + ca – a² – b² – c²) = 0

⇒ (a + b + c)(ab + bc + ca – a² – b² – c²) = 0

Case – I:

a + b + c = 0

Case – II:

ab + bc + ca – a² – b² – c² = 0

⇒ a² + b² + c² – ab – bc – ca = 0

Multiplying 2 on both sides, we have

2(a² + b² + c² – ab – bc – ca) = 0

⇒ 2a² + 2b² + 2c² – 2ab – 2bc – 2ca = 0

⇒ a² – 2ab + b² + b² – 2bc + c² + c² – 2ca + a² = 0

⇒ (a – b)² + (b – c)² + (c – a)² = 0

We know (a – b)² ≥ 0, (b – c)² ≥ 0, (c – a)² ≥ 0

If the sum of three non-negative numbers is zero, then each of the numbers is zero.

⇒ (a – b)² = 0 = (b – c)² = (c – a)²

⇒ a – b = 0 = b – c = c – a

⇒ a = b = c

Thus, if, then either a + b + c = 0 or a = b = c.

Let

Given that Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₁→ R₁ – R₂, we get

Applying R₂→ R₂ – R₃, we get

Expanding the determinant along R₁, we have

Δ = (p – a)[(q – b)(r) – (b)(c – r)] – (b – q)[–a(c – r)]

⇒ Δ = r(p – a)(q – b) – b(p – a)(c – r) + a(b – q)(c – r)

∴ Δ = r(p – a)(q – b) + b(p – a)(r – c) + a(q – b)(r – c)

We have Δ = 0

⇒ r(p – a)(q – b) + b(p – a)(r – c) + a(q – b)(r – c) = 0

On dividing the equation with (p – a)(q – b)(r – c), we get

Thus,

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₂→ R₂ – R₁, we get

Taking the term (x – 2) common from R₂, we get

Applying R₃→ R₃ – R₁, we get

Taking the term (x + 3) common from R₃, we get

Applying C₁→ C₁ + C₃, we get

Expanding the determinant along C₁, we have

Δ = (x – 2)(x + 3)(x – 1)[(–3)(1) – (2)(1)]

⇒ Δ = (x – 2)(x + 3)(x – 1)(–5)

∴ Δ = –5(x – 2)(x + 3)(x – 1)

The given equation is Δ = 0.

⇒ –5(x – 2)(x + 3)(x – 1) = 0

⇒ (x – 2)(x + 3)(x – 1) = 0

Case – I:

x – 2 = 0 ⇒ x = 2

Case – II:

x + 2 = 0 ⇒ x = –3

Case – III:

x – 1 = 0 ⇒ x = 1

Thus, 2 is a root of the equation and its other roots are –3 and 1.

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying C₁→ C₁ + C₂, we get

Applying C₁→ C₁ + C₃, we get

Taking the term (x + a + b + c) common from C₁, we get

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

Expanding the determinant along C₁, we have

Δ = (x + a + b + c)(1)[(x)(x) – (0)(0)]

⇒ Δ = (x + a + b + c)(x)(x)

∴ Δ = x²(x + a + b + c)

The given equation is Δ = 0.

⇒ x²(x + a + b + c) = 0

Case – I:

x² = 0 ⇒ x = 0

Case – II:

x + a + b + c = 0 ⇒ x = –(a + b + c)

Thus, 0 and –(a + b + c) are the roots of the given determinant equation.

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying C₁→ C₁ + C₂, we get

Applying C₁→ C₁ + C₃, we get

Taking the term (3x + a) common from C₁, we get

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

Expanding the determinant along C₁, we have

Δ = (3x + a)(1)[(a)(a) – (0)(0)]

⇒ Δ = (3x + a)(a)(a)

∴ Δ = a²(3x + a)

The given equation is Δ = 0.

⇒ a²(3x + a) = 0

However, a ≠ 0 according to the given condition.

⇒ 3x + a = 0

⇒ 3x = –a

Thus, is the root of the given determinant equation.

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying C₁→ C₁ + C₂, we get

Applying C₁→ C₁ + C₃, we get

Taking the term (3x – 2) common from C₁, we get

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

Expanding the determinant along C₁, we have

Δ = (3x – 2)(1)[(3x – 11)(3x – 11) – (0)(0)]

⇒ Δ = (3x – 2)(3x – 11)(3x – 11)

∴ Δ = (3x – 2)(3x – 11)²

The given equation is Δ = 0.

⇒ (3x – 2)(3x – 11)² = 0

Case – I:

3x – 2 = 0

⇒ 3x = 2

Case – II:

(3x – 11)² = 0

⇒ 3x – 11 = 0

⇒ 3x = 11

Thus, and are the roots of the given determinant equation.

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

Taking (a – x) and (b – x) common from R₂ and R₃, we get

Expanding the determinant along C₁, we have

Δ = (a – x)(b – x)(1)[(1)(b + x) – (1)(a + x)]

⇒ Δ = (a – x)(b – x)[b + x – a – x]

∴ Δ = (a – x)(b – x)(b – a)

The given equation is Δ = 0.

⇒ (a – x)(b – x)(b – a) = 0

However, a ≠ b according to the given condition.

⇒ (a – x)(b – x) = 0

Case – I:

a – x = 0 ⇒ x = a

Case – II:

b – x = 0 ⇒ x = b

Thus, a and b are the roots of the given determinant equation.

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying C₁→ C₁ + C₂, we get

Applying C₁→ C₁ + C₃, we get

Taking the term (x + 9) common from C₁, we get

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

Expanding the determinant along C₁, we have

Δ = (x + 9)(1)[(x – 1)(x – 1) – (0)(0)]

⇒ Δ = (x + 9)(x – 1)(x – 1)

∴ Δ = (x + 9)(x – 1)²

The given equation is Δ = 0.

⇒ x²(x + a + b + c) = 0

Case – I:

x+ 9 = 0 ⇒ x = –9

Case – II:

(x – 1)² = 0

⇒ x – 1 = 0

∴ x = 1

Thus, –9 and 1 are the roots of the given determinant equation.

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

Taking (b – x) and (c – x) common from R₂ and R₃, we get

Expanding the determinant along C₁, we have

Δ = (b – x)(c – x)(1)[(1)(c² + cx + x²) – (1)(b² + bx + x²)]

⇒ Δ = (b – x)(c – x)[c² + cx + x² – b² – bx – x²]

⇒ Δ = (b – x)(c – x)[c² – b² + cx – bx]

⇒ Δ = (b – x)(c – x)[(c – b)(c + b) + (c – b)x]

∴ Δ = (b – x)(c – x)(c – b)(c + b + x)

The given equation is Δ = 0.

⇒ (b – x)(c – x)(c – b)(c + b + x) = 0

However, b ≠ c according to the given condition.

⇒ (b – x)(c – x)(c + b + x) = 0

Case – I:

b – x = 0 ⇒ x = b

Case – II:

c – x = 0 ⇒ x = c

Case – III:

c + b + x = 0 ⇒ x = –(b + c)

Thus, b, c and –(b + c) are the roots of the given determinant equation.

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₂→ R₂ – R₃, we get

Applying C₂→ C₂ – C₁, we get

Applying C₃→ C₃ – C₁, we get

Expanding the determinant along R₂, we have

Δ = – (1)[(–4 – x)(3) – (6)(x – 8)]

⇒ Δ = – [–12 – 3x – 6x + 48]

⇒ Δ = – [– 9x + 36]

∴ Δ = 9x – 36

The given equation is Δ = 0.

⇒ 9x – 36 = 0

⇒ 9x = 36

∴ x = 4

Thus, 4 is the root of the given determinant equation.

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₂→ R₂ – R₁, we get

Taking the term p common from R₂, we get

Applying C₁→ C₁ – C₂, we get

Expanding the determinant along C₁, we have

Δ = p(2 – x)[(1)(1) – (1)(x)]

∴ Δ = p(2 – x)(1 – x)

The given equation is Δ = 0.

⇒ p(2 – x)(1 – x) = 0

Assuming p ≠ 0, we get

⇒ (2 – x)(1 – x) = 0

Case – I:

2 – x = 0 ⇒ x = 2

Case – II:

1 – x = 0 ⇒ x = 1

Thus, 1 and 2 are the roots of the given determinant equation.

Let

We need to find the roots of Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying C₁→ C₁ + C₂, we get

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – 3R₁, we get

Expanding the determinant along C₁, we have

Δ = (1)[(10)(2 – 3sin(3θ)) – (20)(cos(2θ) – sin(3θ))]

⇒ Δ = [20 – 30sin(3θ) – 20cos(2θ) + 20sin(3θ)]

⇒ Δ = 20 – 10sin(3θ) – 20cos(2θ)

From trigonometry, we have sin(3θ) = 3sinθ – 4sin³θ and cos(2θ) = 1 – 2sin²θ.

⇒ Δ = 20 – 10(3sinθ – 4sin³θ) – 20(1 – 2sin²θ)

⇒ Δ = 20 – 30sinθ + 40sin³θ – 20 + 40sin²θ

⇒ Δ = –30sinθ + 40sin²θ + 40sin³θ

∴ Δ = 10(sinθ)(–3 + 4sinθ + 4sin²θ)

The given equation is Δ = 0.

⇒ 10(sinθ)(–3 + 4sinθ + 4sin²θ) = 0

⇒ (sinθ)(–3 + 4sinθ + 4sin²θ) = 0

Case – I:

sin θ = 0 ⇒ θ = kπ, where k ϵ Z

Case – II:

–3 + 4sinθ + 4sin²θ = 0

⇒ 4sin²θ + 4sinθ – 3 = 0

⇒ 4sin²θ + 6sinθ – 2sinθ – 3 = 0

⇒ 2sinθ(2sinθ + 3) – 1(2sinθ + 3) = 0

⇒ (2sinθ – 1)(2sinθ + 3) = 0

⇒ 2sinθ – 1 = 0 or 2sinθ + 3 = 0

⇒ 2sinθ = 1 or 2sinθ = –3

or

However, as –1 ≤ sin θ ≤ 1.

, where k ϵ Z

Thus, kπ and for all integral values of k are the roots of the given determinant equation.

Let

Given that Δ = 0.

We can write the determinant Δ as

Taking a, b and c common from C₁, C₂ and C₃, we get

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying C₁→ C₁ + C₂, we get

Applying C₁→ C₁ + C₃, we get

Taking common from C₁, we get

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

Expanding the determinant along C₁, we have

We have Δ = 0.

It is given that a, b and c are all non-zero.

Thus, when and a, b, c are all non-zero.

Let

Given that Δ = 0.

Recall that the value of a determinant remains same if we apply the operation R_i→ R_i + kR_j or C_i→ C_i + kC_j.

Applying R₂→ R₂ – R₁, we get

Applying R₃→ R₃ – R₁, we get

Expanding the determinant along C₃, we have

⇒ Δ = (c – z)[0 – (–x)(y)] – 0 + z[(a)(y) – (–x)(b – y)]

⇒ Δ = (c – z)(xy) + z[ay + xb – xy]

⇒ Δ = cxy – xyz + ayz + bxz – xyz

∴ Δ = ayz + bxz + cxy – 2xyz

We have Δ = 0

⇒ ayz + bxz + cxy – 2xyz = 0

⇒ ayz + bxz + cxy = 2xyz

Thus, when.

Given: – Vertices of the triangle:

(3, 8), (– 4, 2) and (5, – 1)

We know that,

If vertices of a triangle are (x₁,y₁), (x₂,y₂) and (x₃,y₃), then the area of the triangle is given by:

Now, substituting given value in above formula

Expanding along R₁

sq.units

Thus area of triangle is sq.units

Given: – Vertices of the triangle:

(2, 7) (1, 1) and (10, 8)

We know that,

If vertices of a triangle are (x₁,y₁), (x₂,y₂) and (x₃,y₃), then the area of the triangle is given by:

Now, substituting given value in above formula

Expanding along R₁

sq.units

Thus area of triangle is sq.units

Given: – Vertices of the triangle:

(– 1, – 8), (– 2, – 3) and (3, 2)

We know that,

If vertices of a triangle are (x₁,y₁), (x₂,y₂) and (x₃,y₃), then the area of the triangle is given by:

Now, substituting given value in above formula

Expanding along R₁

sq.units

as area cannot be negative

Therefore, 15 sq.unit is the area

Thus area of triangle is 15 sq.units

Given: – Vertices of the triangle:

(0, 0) (6, 0) and (4, 3)

We know that,

If vertices of a triangle are (x₁,y₁), (x₂,y₂) and (x₃,y₃), then the area of the triangle is given by:

Now, substituting given value in above formula

Expanding along R₁

= 9 sq.units

Thus area of triangle is 9 sq.units

Given: – (1, – 1), (2, 1) and (4, 5) are three points

Tip: – For Three points to be collinear, the area of the triangle formed by these points will be zero

Now, we know that,

vertices of a triangle are (x₁,y₁), (x₂,y₂) and (x₃,y₃), then the area of the triangle is given by:

Now,

Substituting given value in above formula

R.H.S

Expanding along R₁

= 0

= LHS

Since, Area of triangle is zero.

Hence, points are collinear.

Given: – (3, – 2), (8, 8) and (5, 2) are three points

Tip: – For Three points to be collinear, the area of triangle formed by these points will be zero

Now, we know that,

vertices of a triangle are (x₁,y₁), (x₂,y₂) and (x₃,y₃), then the area of the triangle is given by:

Now,

Substituting given value in above formula

R.H.S

Expanding along R₁

= 0

= LHS

Since, Area of triangle is zero

Hence, points are collinear.

Given: – (2, 3), (– 1, – 2) and (5, 8) are three points

Tip: – For Three points to be collinear, the area of the triangle formed by these points will be zero

Now, we know that,

vertices of a triangle are (x₁,y₁), (x₂,y₂) and (x₃,y₃), then the area of the triangle is given by:

Now,

Substituting given value in above formula

R.H.S

Expanding along R₁

= 0

= LHS

Since, Area of triangle is zero

Hence, points are collinear.

Given: – (a, 0), (o, b) and (1, 1) are collinear points

To Prove: – a + b = ab

Proof: –

Tip: – If Three points to be collinear, then the area of the triangle formed by these points will be zero

Now, we know that,

vertices of a triangle are (x₁,y₁), (x₂,y₂) and (x₃,y₃), then the area of the triangle is given by:

Thus

Expanding along R₁

⇒

⇒

⇒

⇒ a + b = ab

Hence Proved

Given: – (a, b) (a’, b’) and (a – a’, b – b’) are points and ab’ = a’b

To Prove: – (a, b) (a’, b’) and (a – a’, b – b’) are collinear points

Proof: –

Tip: – If three points to be collinear, then the area of the triangle formed by these points will be zero.

Now, we know that,

vertices of a triangle are (x₁,y₁), (x₂,y₂) and (x₃,y₃), then the area of the triangle is given by:

Thus

Expanding along R₁

⇒

⇒

⇒

⇒ ab^’ – a^’b = 0

⇒ ab^’ = a^’b

Hence, Proved.

Given: – (1, – 5), (– 4, 5) and (λ, 7) are collinear

Tip: – For Three points to be collinear, the area of the triangle formed by these points will be zero

Now, we know that,