Let a_1, a_2, a_3, dots be an A.P. and g_1, g | vedclass

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(D) Let the $A$.$P$. be $a_n = a + (n-1)d$ and the $G$.$P$. be $g_n = ar^{n-1}$.Given $a_1 = g_1 = a$.From $a_2 + g_2 = 1$,we have $(a+d) + ar = 1 \im

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$55$

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(D) Let the $A$.$P$. be $a_n = a + (n-1)d$ and the $G$.$P$. be $g_n = ar^{n-1}$.Given $a_1 = g_1 = a$.From $a_2 + g_2 = 1$,we have $(a+d) + ar = 1 \implies d = 1 - a - ar$.From $a_3 + g_3 = 4$,we have $(a+2d) + ar^2 = 4$.Substitute $d$ into the second equation: $a + 2(1 - a - ar) + ar^2 = 4$.$a + 2 - 2a - 2ar + ar^2 = 4 \implies ar^2 - 2ar - a = 2 \implies a(r^2 - 2r - 1) = 2$.Since $a = 1/(1+r)$,we substitute: $\frac{r^2 - 2r - 1}{r+1} = 2$.$r^2 - 2r - 1 = 2r + 2 \implies r^2 - 4r - 3 = 0$. This does not yield integer solutions. Re-evaluating the system for standard integer constraints: if $a = -1/2$ and $r = 3$,then $a_1 = -1/2, a_2 = -1/2 + d, g_2 = -3/2$. $a_2 + g_2 = -2 + d = 1 \implies d = 3$. Then $a_3 = -1/2 + 6 = 5.5$ and $g_3 = -1/2(9) = -4.5$. $a_3 + g_3 = 5.5 - 4.5 = 1$ (Incorrect).Correcting the system: Let $a=1, r=2$. $a_1=1, g_1=1$. $a_2+g_2 = (1+d)+2 = 1 \implies d = -2$. $a_3+g_3 = (1-4)+4 = 1$ (Incorrect).Using $a=-1, r=3$: $a_1=-1, g_1=-1$. $a_2+g_2 = (-1+d)-3 = 1 \implies d=5$. $a_3+g_3 = (-1+10)-9 = 0$ (Incorrect).Given the options,for $a=-1/2, r=3$,$a_{10} = -0.5 + 9(3) = 26.5$ and $g_5 = -0.5(81) = -40.5$. Sum $= -14$. Testing $a=1, r=3$: $a_1=1, g_1=1$. $a_2+g_2 = 1+d+3 = 1 \implies d=-3$. $a_3+g_3 = 1-6+9 = 4$. This matches! So $a_n = 1 + (n-1)(-3) = 4 - 3n$ and $g_n = 1(3)^{n-1}$.$a_{10} = 4 - 30 = -26$. $g_5 = 3^4 = 81$.$a_{10} + g_5 = -26 + 81 = 55$.

Let $a_1, a_2, a_3, \dots$ be an $A$.$P$. and $g_1, g_2, g_3, \dots$ be an increasing $G$.$P$. If $a_1 = g_1$ and $a_2 + g_2 = 1$ and $a_3 + g_3 = 4$,then $a_{10} + g_5$ is equal to:

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