# Properties

 Degree 2 Conductor 5077 Sign $-1$ Self-dual yes Motivic weight 1

# Related objects

## Dirichlet series

 L(E,s)  = 1 − 2·2-s − 3·3-s + 2·4-s − 4·5-s + 6·6-s − 4·7-s + 6·9-s + 8·10-s − 6·11-s − 6·12-s − 4·13-s + 8·14-s + 12·15-s − 4·16-s − 4·17-s − 12·18-s − 7·19-s − 8·20-s + 12·21-s + 12·22-s − 6·23-s + 11·25-s + 8·26-s − 9·27-s − 8·28-s − 6·29-s − 24·30-s + ⋯
 L(s,E)  = 1 − 1.414·2-s − 1.732·3-s + 4-s − 1.788·5-s + 2.449·6-s − 1.511·7-s + 2·9-s + 2.529·10-s − 1.809·11-s − 1.732·12-s − 1.109·13-s + 2.138·14-s + 3.098·15-s − 16-s − 0.970·17-s − 2.828·18-s − 1.605·19-s − 1.788·20-s + 2.618·21-s + 2.558·22-s − 1.251·23-s + 2.2·25-s + 1.568·26-s − 1.732·27-s − 1.511·28-s − 1.114·29-s − 4.381·30-s + ⋯

## Functional equation

\begin{align} \Lambda(E,s)=\mathstrut & 5077 ^{s/2} \Gamma_{\C}(s) \cdot L(E,s)\cr =\mathstrut & - \Lambda(E, 2-s) \end{align}
\begin{align} \Lambda(s,E)=\mathstrut & 5077 ^{s/2} \Gamma_{\C}(s+1/2) \cdot L(s,E)\cr =\mathstrut & - \Lambda(1-s,E) \end{align}

## Invariants

 $d$ = $2$ $N$ = $5077$ $\varepsilon$ = $-1$ weight = 1 Sato-Tate : $\mathrm{SU}(2)$ primitive : yes self-dual : yes analytic rank = 3 Selberg data = $(2,\ 5077,\ (\ :1/2),\ -1)$ $L(E,1)$ $=$ $0$ $L(\frac12,E)$ $=$ $0$ $L(E,\frac{3}{2})$ not available $L(1,E)$ not available

## Euler product

$L(A,s) = \prod_{p \text{ prime}} F_p(p^{-s})^{-1}$ where, for $p \neq 5077$, $F_p(T) = 1 - a_p T + p T^2 .$If $p = 5077$, then $F_p$ is a polynomial of degree at most 1.
$p$$F_p$
bad5077$1+T$
good2$1+2T+2T^{2}$
3$1+3T+3T^{2}$
5$1+4T+5T^{2}$
7$1+4T+7T^{2}$
11$1+6T+11T^{2}$
13$1+4T+13T^{2}$
17$1+4T+17T^{2}$
19$1+7T+19T^{2}$
23$1+6T+23T^{2}$
29$1+6T+29T^{2}$
31$1+2T+31T^{2}$
37$1+37T^{2}$
41$1+41T^{2}$
43$1+8T+43T^{2}$
47$1+9T+47T^{2}$
53$1+9T+53T^{2}$
59$1+11T+59T^{2}$
61$1+2T+61T^{2}$
67$1+12T+67T^{2}$
71$1+8T+71T^{2}$
73$1+14T+73T^{2}$
79$1-9T+79T^{2}$
83$1+2T+83T^{2}$
89$1-11T+89T^{2}$
97$1-6T+97T^{2}$
$$$L(s,E) = \prod_{p\ \mathrm{bad}} (1- a(p) p^{-s})^{-1} \prod_{p\ \mathrm{good}} (1- a(p) p^{-s} + p^{-2s})^{-1}$$$