It is given that, the centres of circles C₁, C₂ and C₃ are co-linear,

$$ \therefore $$ $$\left| {\matrix{ 0 & 0 & 1 \cr 3 & 4 & 1 \cr h & k & 1 \cr } } \right| = 0 \Rightarrow 4h = 3k$$ ....(i)

and MN is the length of diameter of circle C₃, so

MN = $$3 + \sqrt {{{(3 - 0)}^2} + {{(4 - 0)}^2}} + 4$$

= $$3 + 5 + 4 = 12$$

So, radius of circle C₃, r = 6 ......(ii)

Since, the circle C₃ touches C₁ at M and C₂ at N, so

|C₁ C₃| = |r $$-$$ 3|

$$ \Rightarrow $$ $$\sqrt {{h^2} + {k^2}} = 3$$

$$ \Rightarrow $$ h² + k² = 9 .....(iii)

From Eqs. (i) and (iii), we get

$${h^2} + {{16{h^2}} \over 9} = 9 \Rightarrow 25{h^2} = 81$$

$$ \Rightarrow h = + {9 \over 5}$$ and $$k = + {{12} \over 5}$$

So, $$2h + k = {{18} \over 5} + {{12} \over 5} = 6$$

Now, equation common chord XY of circles C₁ and C₂ is

C₁ $$-$$ C₂ = 0

$$ \Rightarrow $$ 6x + 8y = 18

$$ \Rightarrow $$ 3x + 4y = 9 ....(iv)

Now, PY² = GY² $$-$$ GP²

= $$9 - {{81} \over {25}} = {{144} \over {25}}$$

$$ \Rightarrow $$ PY = $${{12} \over 5}$$

$$ \because $$ $$XY = 2PY = 2 \times {{12} \over 5} = {{24} \over 5}$$

Similarly, equation of ZW is 3x + 4y = 9.

Now, So, length of perpendicular from C₃ to

$$ZW = {{\left| {3\left( {{9 \over 5}} \right) + 4\left( {{{12} \over 5}} \right) - 9} \right|} \over 5} = {6 \over 5}$$

So, $$P{W^2} = {C_3}{W^2} - {C_3}{P^2} = 36 - {{36} \over {25}} = {{864} \over {25}}$$

{$$ \because $$ C₃W = r = 6}

$$ \Rightarrow $$ $$PW = {{12\sqrt 6 } \over 5}$$

$$ \because $$ $$ZW = 2PW = {{24\sqrt 6 } \over 5}$$

$$ \therefore $$ $${{length\,of\,ZW} \over {length\,of\,XY}} = \sqrt 6 $$

So, combination (ii), Q is only correct.

Hence, option (c) is correct.