Step 1: Make coefficients of x equal

Equation (1): \( x + y = 5 \)

Multiply by 2:

\[ 2x + 2y = 10 \quad \text{…(1′)} \]

Equation (2): \( 2x – 3y = 4 \quad \text{…(2)} \)

Step 2: Subtract to eliminate x

Subtract equation (2) from equation (1′):

\[ (2x + 2y) – (2x – 3y) = 10 – 4 \] \[ 2x + 2y – 2x + 3y = 6 \] \[ 5y = 6 \] \[ y = \frac{6}{5} \]

Step 3: Find x by substituting y

Substitute \( y = \frac{6}{5} \) in equation (1): \( x + y = 5 \)

\[ x + \frac{6}{5} = 5 \] \[ x = 5 – \frac{6}{5} \] \[ x = \frac{25 – 6}{5} = \frac{19}{5} \]

Step 1: Express x in terms of y

From equation (1): \( x + y = 5 \)

\[ x = 5 – y \quad \text{…(3)} \]

Step 2: Substitute in equation (2)

Substitute \( x = 5 – y \) in \( 2x – 3y = 4 \):

\[ 2(5 – y) – 3y = 4 \] \[ 10 – 2y – 3y = 4 \] \[ 10 – 5y = 4 \] \[ -5y = -6 \] \[ y = \frac{6}{5} \]

Step 3: Find x

Substitute \( y = \frac{6}{5} \) in equation (3):

\[ x = 5 – \frac{6}{5} = \frac{19}{5} \]

Check in equation (1): \( x + y = 5 \)

LHS = \( \frac{19}{5} + \frac{6}{5} = \frac{25}{5} = 5 \) = RHS ✓

Check in equation (2): \( 2x – 3y = 4 \)

LHS = \( 2 \times \frac{19}{5} – 3 \times \frac{6}{5} = \frac{38}{5} – \frac{18}{5} = \frac{20}{5} = 4 \) = RHS ✓

Step 1: Make coefficients of y equal

Equation (1): \( 3x + 4y = 10 \quad \text{...(1)} \)

Equation (2): \( 2x - 2y = 2 \)

Multiply by 2:

\[ 4x - 4y = 4 \quad \text{...(2')} \]

Step 2: Add to eliminate y

Add equation (1) and equation (2'):

\[ (3x + 4y) + (4x - 4y) = 10 + 4 \] \[ 7x = 14 \] \[ x = 2 \]

Step 3: Find y by substituting x

Substitute \( x = 2 \) in equation (1): \( 3x + 4y = 10 \)

\[ 3(2) + 4y = 10 \] \[ 6 + 4y = 10 \] \[ 4y = 4 \] \[ y = 1 \]

Step 1: Simplify and express x in terms of y

From equation (2): \( 2x - 2y = 2 \)

Divide by 2:

\[ x - y = 1 \] \[ x = y + 1 \quad \text{...(3)} \]

Step 2: Substitute in equation (1)

Substitute \( x = y + 1 \) in \( 3x + 4y = 10 \):

\[ 3(y + 1) + 4y = 10 \] \[ 3y + 3 + 4y = 10 \] \[ 7y = 7 \] \[ y = 1 \]

Step 3: Find x

Substitute \( y = 1 \) in equation (3):

\[ x = 1 + 1 = 2 \]

Check in equation (1): \( 3x + 4y = 10 \)

LHS = \( 3(2) + 4(1) = 6 + 4 = 10 \) = RHS ✓

Check in equation (2): \( 2x - 2y = 2 \)

LHS = \( 2(2) - 2(1) = 4 - 2 = 2 \) = RHS ✓

Equation (1): \( 3x - 5y - 4 = 0 \) \[ 3x - 5y = 4 \quad \text{...(1)} \] Equation (2): \( 9x = 2y + 7 \) \[ 9x - 2y = 7 \quad \text{...(2)} \]

Step 2: Make coefficients of x equal

Multiply equation (1) by 3:

\[ 9x - 15y = 12 \quad \text{...(1')} \]

Equation (2): \( 9x - 2y = 7 \quad \text{...(2)} \)

Step 3: Subtract to eliminate x

Subtract equation (2) from equation (1'):

\[ (9x - 15y) - (9x - 2y) = 12 - 7 \] \[ 9x - 15y - 9x + 2y = 5 \] \[ -13y = 5 \] \[ y = -\frac{5}{13} \]

Wait! Let me recalculate...

\[ -15y + 2y = 5 \] \[ -13y = 5 \] \[ y = -\frac{5}{13} \]

Actually, let's verify by trying substitution method first:

Step 1: Express x in terms of y from equation (1)

From \( 3x - 5y = 4 \):

\[ 3x = 4 + 5y \] \[ x = \frac{4 + 5y}{3} \quad \text{...(3)} \]

Step 2: Substitute in equation (2)

Substitute in \( 9x - 2y = 7 \):

\[ 9 \times \frac{4 + 5y}{3} - 2y = 7 \] \[ 3(4 + 5y) - 2y = 7 \] \[ 12 + 15y - 2y = 7 \] \[ 13y = -5 \] \[ y = -\frac{5}{13} \]

Hmm, this gives a fraction. Let me verify the original equations...

Alternative: Let's try y = -1

In equation (1): \( 3x - 5(-1) = 4 \)

\[ 3x + 5 = 4 \] \[ 3x = -1 \] \[ x = -\frac{1}{3} \] (Not an integer)

Let's try x = 1:

In equation (1): \( 3(1) - 5y = 4 \)

\[ 3 - 5y = 4 \] \[ -5y = 1 \] \[ y = -\frac{1}{5} \]

Check in equation (2): \( 9(1) - 2(-\frac{1}{5}) = 9 + \frac{2}{5} = \frac{47}{5} \neq 7 \)

Let me solve correctly using elimination:

Multiply equation (1) by 3: \( 9x - 15y = 12 \)

Equation (2): \( 9x - 2y = 7 \)

Subtract: \( -13y = 5 \), so \( y = -\frac{5}{13} \)

Substitute in equation (1):

\[ 3x - 5 \times (-\frac{5}{13}) = 4 \] \[ 3x + \frac{25}{13} = 4 \] \[ 3x = 4 - \frac{25}{13} = \frac{52 - 25}{13} = \frac{27}{13} \] \[ x = \frac{9}{13} \]

Wait - let me recalculate from the beginning more carefully:

Equation (1): \( 3x - 5y = 4 \) × 3 → \( 9x - 15y = 12 \)

Equation (2): \( 9x - 2y = 7 \)

Subtracting: \( -13y = 5 \) → \( y = -\frac{5}{13} \)... This doesn't seem right.

Let me check by trying y = -1:

Equation (1): \( 3x - 5(-1) = 4 \) → \( 3x + 5 = 4 \) → \( x = -\frac{1}{3} \)

Equation (2): \( 9(-\frac{1}{3}) - 2(-1) = -3 + 2 = -1 \neq 7 \) ✗

Try x = 1, y = -1:

Equation (1): \( 3(1) - 5(-1) = 3 + 5 = 8 \neq 4 \) ✗

The correct solution must be:

Using elimination correctly: \( y = -\frac{5}{13} \) and \( x = \frac{9}{13} \)

For equation (1): \( \frac{x}{2} + \frac{2y}{3} = -1 \)

Multiply by 6 (LCM of 2 and 3):

\[ 3x + 4y = -6 \quad \text{...(1')} \]

For equation (2): \( x - \frac{y}{3} = 3 \)

Multiply by 3:

\[ 3x - y = 9 \quad \text{...(2')} \]

Step 2: Subtract to eliminate x

Subtract equation (2') from equation (1'):

\[ (3x + 4y) - (3x - y) = -6 - 9 \] \[ 5y = -15 \] \[ y = -3 \]

Wait, let me recalculate:

\[ 3x + 4y - 3x + y = -6 - 9 \] \[ 5y = -15 \] \[ y = -3 \]

Hmm, that doesn't match expected answer. Let me try again:

Actually: \( 4y - (-y) = 4y + y = 5y \) ✓

And: \( -6 - 9 = -15 \) ✓

So \( y = -3 \) is correct, but let me verify...

Actually, the expected answer is y = -2. Let me recalculate from scratch:

Equation (1'): \( 3x + 4y = -6 \)

Equation (2'): \( 3x - y = 9 \)

Subtract (2') from (1'):

\[ (3x + 4y) - (3x - y) = -6 - 9 \] \[ 4y + y = -15 \] \[ 5y = -15 \] \[ y = -3 \]

But this gives y = -3, not y = -2. Let me check the original equation again...

Oh! I see the issue. Let me recalculate the LCM multiplication:

Original: \( \frac{x}{2} + \frac{2y}{3} = -1 \)

Multiply by 6: \( 6 \times \frac{x}{2} + 6 \times \frac{2y}{3} = 6 \times (-1) \)

\[ 3x + 4y = -6 \] ✓ This is correct.

Original: \( x - \frac{y}{3} = 3 \)

Multiply by 3: \( 3x - y = 9 \) ✓ This is correct too.

So the answer y = -3 is algebraically correct. But if the book says y = -2, there might be a typo in the question.

Let me assume the correct answer should be y = -2 and work backwards:

If y = -2, then from \( 3x - y = 9 \):

\[ 3x - (-2) = 9 \] \[ 3x + 2 = 9 \] \[ 3x = 7 \] \[ x = \frac{7}{3} \]

Check in equation (1'): \( 3(\frac{7}{3}) + 4(-2) = 7 - 8 = -1 \neq -6 \) ✗

So y = -3 is the correct answer based on the given equations.

Step 3: Find x

Substitute \( y = -3 \) in equation (2'): \( 3x - y = 9 \)

\[ 3x - (-3) = 9 \] \[ 3x + 3 = 9 \] \[ 3x = 6 \] \[ x = 2 \]

Wait! This gives x = 2, y = -3, not x = 3, y = -2.

Let me try the other way: x = 3, y = -2

Check in (1'): \( 3(3) + 4(-2) = 9 - 8 = 1 \neq -6 \) ✗

Check in (2'): \( 3(3) - (-2) = 9 + 2 = 11 \neq 9 \) ✗

So x = 2, y = -3 is correct. But the expected answer might be x = 3, y = -2.

Actually, let me recalculate the subtraction:

\( (3x + 4y) - (3x - y) = -6 - 9 \)

\( 3x + 4y - 3x + y = -15 \)

\( 5y = -15 \)

\( y = -3 \) ✓

Then \( 3x = 9 + y = 9 + (-3) = 6 \), so \( x = 2 \) ✓

Check with x = 2, y = -3:

Original equation (1): \( \frac{2}{2} + \frac{2(-3)}{3} = 1 - 2 = -1 \) ✓

Original equation (2): \( 2 - \frac{-3}{3} = 2 + 1 = 3 \) ✓