On q-series and continued fractions

Abstract In this paper we have established interesting results involving continued fraction. Special cases of the result established herein have also been discussed.


Introduction, notations and definitions
Continued fractions have been playing a very important role in number theory and classical analysis ever since the times of Euler and Gauss. Generalized hypergeometric series, both ordinary and basic, have been a very significant tool in the derivation of continued fraction representations. Bhargava and Adiga (1984), Bhragava, Adiga, and Somashekara (1987), Singh (2000, 2011), Srivastava, Singh, and Singh (2015) and many others have established a good number of results involving q-series and continued fractions. One is also referred to see the papers Cao and Srivastava (2013), Choi and Srivastava (2014), Luo and Srivastava (2011), Srivastava (2011), Srivasatava and Choi (2012) and Srivastava and Choudhary (2015) for useful and interesting similar results. In what follows, we shall use the following usual notations and definitions. Some interesting applications in the direction of quantum calculus can be seen in Mishra, Khatri, Mishra, and Deepmala (2013), Mishra, Khan, Khatri, and Mishra (2013), Mishra, Khatri, and Mishra (2012, 2013a, 2013b, Mishra, Sharma, and Mishra (2016), Mishra (2016a, 2016b), and Singh, Gairola, and Deepmala (2016).

Let
Following (Srivastava and Karlsson, 1985, 272 p. 347) a basic hypergeometric series is defined as,

ABOUT THE AUTHOR
Vishnu Narayan Mishra received the PhD in Mathematics from Indian Institute of Technology, Roorkee. His research interests are in the areas of pure and applied mathematics. He has published more than 110 research articles in reputed international journals of mathematical and engineering sciences. He is a referee and an editor of several international journals in frame of Mathematics. He guided many postgraduate and PhD students. Citations of his research contributions can be found in many books and monographs, PhD thesis and scientific journal articles.

PUBLIC INTEREST STATEMENT
This paper is interesting and useful from application point of view. Approximate values of many known functions can be evaluated with the help of continued fractions. Research scholars will get motivation through this paper.
An expression of the form is said to be a finite continued fraction and as n → ∞, it is called an infinite continued fraction. It is also represented by,

Main results
In this section we shall establish our main result: Proof of (1.1) In order to prove (1.1), let us consider the ratio, Iterating this process, we get Now, by an appeal of (Jones & Thoren, 1980, (2.3.14), p. 33) we have Finally, taking a = 1 in (1.5) and using Rogers-Fine identity (Andrews & Berndt, 2005, (9.1.1), p. 223) we get (1.1).

Special cases
In this section we shall discuss some special cases of the results (1.1) and (1.5).
(i) Putting z/b for z in (1.1) and then taking b → ∞ and c = 0 in it we get,  (iv) Replacing q by q 2 in (2.1) and then taking z = −aq in it we find, (v) Taking c = bq in (1.1) we find, (vi) Replacing q by q 5 and then taking z = q j and b = q i in (2.6) we have, (vii) For j = i, (2.7) yields, which gives the continued fraction representation of a Lambert series and is believed to be new.

Funding
The authors received no direct funding for this research.