The post has been divided into sections to show some patterns. **I. Parameter $s=\frac12$** Given the **nome** $q = e^{\pi i\tau}$ and the Jacobi theta functions $\vartheta_n(0,q)$. Define the [modular lambda function][1], $$\alpha = \frac{16}{\left(\tfrac{\eta(\tau/2)}{\eta(2\tau)}\right)^8+16} = \left(\frac{\sqrt2\,\eta(\tau/2)\eta^2(2\tau)}{\eta^3(\tau)}\right)^8 = \left(\frac{\vartheta_2(0,q)}{\vartheta_3(0,q)}\right)^4$$ Then we propose for appropriate $\tau$ the ratios below are algebraic numbers, \begin{align} \left(\frac{\vartheta_2(0,q)}{\sqrt{_2F_1\big(\tfrac12,\tfrac12,1,\alpha\big)}}\right)^4 &\overset{\color{red}?}=\alpha\\ \left(\frac{\vartheta_4(0,q)}{\sqrt{_2F_1\big(\tfrac12,\tfrac12,1,\alpha\big)}}\right)^4 &\overset{\color{red}?}=1-\alpha\\ \left(\frac{\vartheta_3(0,q)}{\sqrt{_2F_1\big(\tfrac12,\tfrac12,1,\alpha\big)}}\right)^4 &\overset{\color{red}?}=1 \end{align} Note that adding the first two implies the third. Hence, $$\big(\vartheta_2(0,q)\big)^4+\big(\vartheta_4(0,q)\big)^4 = \big(\vartheta_3(0,q)\big)^4$$ which is known to be true. As eta quotients in the same order of $\vartheta_n(0,q)$ above, $$\left(\frac{2\eta^2(2\tau)}{\eta(\tau)}\right)^4+\left(\frac{\eta^2\big(\tfrac{\tau}2\big)}{\eta(\tau)}\right)^4 = \left(\frac{\eta^5(\tau)}{\eta^2\big(\tfrac{\tau}2\big)\,\eta^2(2\tau)}\right)^4 \overset{\color{red}?}= \left(\frac{\eta^4\big(\tfrac{\tau}2\big)+4\eta^4(2\tau)}{2\eta^3(\tau)}\right)^4$$ where the sum has a nice *alternative* form to be consistent with the cubic version below. --- **II. Parameter $s=\frac13$** Given the ***square*** of the nome, so $q = e^{2\pi i\tau}$ and the *Borwein cubic theta functions* $a(q),b(q),c(q)$. Define, $$\beta = \left(\frac{3}{\left(\tfrac{\eta(\tau/3)}{\eta(3\tau)}\right)^3+3}\right)^3=\left(\frac{c(q)}{a(q)}\right)^3$$ Then we propose, \begin{align} \left(\frac{c(q)}{_2F_1\big(\tfrac13,\tfrac23,1,\beta\big)}\right)^3 &\overset{\color{red}?}=\beta\\ \left(\frac{b(q)}{_2F_1\big(\tfrac13,\tfrac23,1,\beta\big)}\right)^3 &\overset{\color{red}?}=1-\beta\\ \left(\frac{a(q)}{_2F_1\big(\tfrac13,\tfrac23,1,\beta\big)}\right)^3 &\overset{\color{red}?}=1 \end{align} Adding the first two implies the third, $$\big(c(q)\big)^3+\big(b(q)\big)^3=\big(a(q)\big)^3$$ which is also known to be true. As eta quotients, $$\left(\frac{3\eta^3(3\tau)}{\eta(\tau)}\right)^3+\left(\frac{\eta^3(\tau)}{\eta(3\tau)}\right)^3 =\left(\frac{\eta^3(\tau)+9\eta^3(9\tau)}{\eta(3\tau)}\right)^3$$ --- **III. Parameter $s=\frac14$** Given the ***square*** of the nome $q = e^{2\pi i\tau}$. Define, $$\gamma = \left(\frac{8}{\left(\tfrac{\eta(\tau/2)}{\eta(2\tau)}\right)^8+8}\right)^2 = \left(\frac{C(q)}{A(q)}\right)^2$$ Then, \begin{align} \left(\frac{C(q)}{_2F_1\big(\tfrac14,\tfrac34,1,\gamma\big)^2}\right)^2 &\overset{\color{red}?}=\gamma\\ \left(\frac{B(q)}{_2F_1\big(\tfrac14,\tfrac34,1,\gamma\big)^2}\right)^2 &\overset{\color{red}?}=1-\gamma\\ \left(\frac{A(q)}{_2F_1\big(\tfrac14,\tfrac34,1,\gamma\big)^2}\right)^2 &\overset{\color{red}?}=1 \end{align} The first two implies the third, $$\big(C(q)\big)^2+\big(B(q)\big)^2=\big(A(q)\big)^2$$ where $C(q), B(q), A(q)$ are defined by the eta quotients, $$\left(\frac{8\eta^8(2\tau)}{\eta^4(\tau)}\right)^2+\left(\frac{\eta^8(\tau)}{\eta^4(2\tau)}\right)^2=\left(\frac{\eta^8(\tau)+32\eta^8(4\tau)}{\eta^4(2\tau)}\right)^2$$ Note that, $$\frac{24}{A(q)-1}= \frac1{q} -1 - 3q + 6q^2 + q^3 - 20q^4 + 24q^5 + 38q^6 - 132q^7 + \dots$$ which seems to be [A335227][2]. --- **IV. Parameter $s=\frac16$** (*Unfinished.*) --- **V. Context** These observations arose from evaluations of the *complete elliptic integral of the first kind*, $K(k)$. For ex., given the *tribonacci constant* $T$, the real root of $T^3-T^2-T-1=0$, then, $$K(k_{11}) = \frac{\pi\,(2T)^{2/3}}{2\;}\times \frac{\Gamma\big(\tfrac1{11}\big) \Gamma\big(\tfrac3{11}\big) \Gamma\big(\tfrac4{11}\big) \Gamma\big(\tfrac5{11}\big) \Gamma\big(\tfrac9{11}\big)}{11^{1/4}(2\pi)^3}$$ Manipulating the $s=\frac12$ relations above, we can have a *much* shorter version, $$K(k_{11}) = \frac{\pi\,(2T)^{4/3}}{2\;}\times\eta^2\Big(\tfrac{1+\sqrt{-11}}2\Big)\quad\quad$$ Equating the two formulas, this also gives the explicit evaluation of $\eta(\tau)$. --- **VI. Question** **Q:** Are the proposed relations $M\overset{\color{red}?}=N$ with the red question marks in fact true? [1]: https://en.wikipedia.org/wiki/Modular_lambda_function#Relations_to_other_functions [2]: https://https%20:%20//%20oeis.org/A335227