# q-expansion of newform 1650.2.c.d, downloaded from the LMFDB on 27 June 2026. # We generate the q-expansion using the Hecke eigenvalues a_p at the primes. # Each a_p is given as a linear combination # of the following basis for the coefficient ring. def make_data(): from sage.all import prod, floor, prime_powers, gcd, QQ, primes_first_n, next_prime, RR def discrete_log(elts, gens, mod): # algorithm 2.2, page 16 of https://arxiv.org/abs/0903.2785 def table_gens(gens, mod): T = [1] n = len(gens) r = [None]*n s = [None]*n for i in range(n): beta = gens[i] r[i] = 1 N = len(T) while beta not in T: for Tj in T[:N]: T.append((beta*Tj) % mod) beta = (beta*gens[i]) % mod r[i] += 1 s[i] = T.index(beta) return T, r, s T, r, s = table_gens(gens, mod) n = len(gens) N = [ prod(r[:j]) for j in range(n) ] Z = lambda s: [ (floor(s/N[j]) % r[j]) for j in range(n)] return [Z(T.index(elt % mod)) for elt in elts] def extend_multiplicatively(an): for pp in prime_powers(len(an)-1): for k in range(1, (len(an) - 1)//pp + 1): if gcd(k, pp) == 1: an[pp*k] = an[pp]*an[k] from sage.all import PolynomialRing, NumberField R = PolynomialRing(QQ, "x") f = R(poly_data) K = NumberField(f, "a") betas = [K.gens()[0]**i for i in range(len(poly_data))] convert_elt_to_field = lambda elt: sum(c*beta for c, beta in zip(elt, betas)) # convert aps to K elements primes = primes_first_n(len(aps_data)) good_primes = [p for p in primes if not p.divides(level)] aps = map(convert_elt_to_field, aps_data) if not hecke_ring_character_values: # trivial character char_values = dict(zip(good_primes, [1]*len(good_primes))) else: gens = [elt[0] for elt in hecke_ring_character_values] gens_values = [convert_elt_to_field(elt[1]) for elt in hecke_ring_character_values] char_values = dict([( p,prod(g**k for g, k in zip(gens_values, elt))) for p, elt in zip(good_primes, discrete_log(good_primes, gens, level)) ]) an_list_bound = next_prime(primes[-1]) an = [0]*an_list_bound an[1] = 1 from sage.all import PowerSeriesRing PS = PowerSeriesRing(K, "q") for p, ap in zip(primes, aps): if p.divides(level): euler_factor = [1, -ap] else: euler_factor = [1, -ap, p**(weight - 1) * char_values[p]] k = RR(an_list_bound).log(p).floor() + 1 foo = (1/PS(euler_factor)).padded_list(k) for i in range(1, k): an[p**i] = foo[i] extend_multiplicatively(an) return PS(an) level = 1650 weight = 2 poly_data = [1, 0, 1] # The basis for the coefficient ring is just the power basis # in the root of the defining polynomial above. hecke_ring_character_values = [[551, [1, 0]], [727, [-1, 0]], [1201, [1, 0]]] aps_data = [[0, -1], [0, -1], [0, 0], [0, 2], [-1, 0], [0, 4], [0, -6], [4, 0], [0, -6], [-6, 0], [8, 0], [0, -10], [6, 0], [0, -8], [0, -6], [0, 0], [0, 0], [8, 0], [0, -4], [6, 0], [0, -2], [-14, 0], [0, 12], [6, 0], [0, 14], [6, 0], [0, 4], [0, -12], [4, 0], [0, -18], [0, 14], [-12, 0], [0, -18], [4, 0], [6, 0], [-10, 0], [0, 2], [0, 4], [0, 12], [0, -6], [-24, 0], [-22, 0], [18, 0], [0, -14], [0, 6], [4, 0], [8, 0], [0, 16], [0, -12], [22, 0], [0, 18], [12, 0], [-10, 0], [0, 0], [0, -30], [0, 0], [24, 0], [2, 0], [0, -16], [-6, 0], [0, -8], [0, 6], [0, 20], [-18, 0], [0, -26], [0, 12], [-4, 0], [0, 2], [0, 36], [4, 0], [0, 6], [12, 0], [0, 8], [0, -20], [-20, 0], [0, -6], [0, 0], [0, 26], [30, 0], [34, 0], [-24, 0], [-10, 0], [0, 0], [0, -26], [10, 0], [0, 24], [-6, 0], [0, -10], [42, 0], [0, 4], [0, -12], [24, 0], [0, 20], [12, 0], [4, 0], [0, -12], [-24, 0], [-18, 0], [0, 16], [20, 0], [0, -28], [0, 18], [0, 12], [-18, 0], [-28, 0], [0, -34], [0, 24], [0, 30], [-30, 0], [-22, 0], [0, 14], [0, 16], [0, -30], [-44, 0], [-16, 0], [6, 0], [0, 4], [0, 6], [0, 36], [-36, 0], [-22, 0], [0, -14], [0, 30], [0, 24], [20, 0], [-6, 0], [-26, 0], [-30, 0], [0, -28], [0, 4], [-8, 0], [0, -36], [8, 0], [0, -34], [18, 0], [34, 0], [0, 0], [0, 32], [0, 0], [42, 0], [8, 0], [-18, 0], [0, -8], [0, -12], [-14, 0], [-18, 0], [0, -8], [0, 54], [-20, 0], [0, -42], [0, -52], [-30, 0], [0, 28], [0, -36], [0, 20], [-42, 0], [-2, 0], [-30, 0], [0, -22], [-18, 0], [0, 12], [0, 42], [0, 14], [0, 0], [0, 54], [0, -30], [56, 0], [0, 44], [34, 0], [0, -12], [12, 0], [50, 0], [-60, 0], [0, 46], [40, 0], [6, 0], [-4, 0], [36, 0], [0, -2], [4, 0], [0, 32], [-60, 0], [0, -14], [0, 6], [0, -54], [12, 0], [0, 56], [0, 4], [-14, 0], [0, 0], [0, 10], [0, -60], [-28, 0], [48, 0], [0, -12], [0, -66], [-22, 0], [0, 22], [0, 30], [0, 24], [54, 0], [2, 0], [0, 26], [46, 0], [48, 0], [0, -12], [4, 0], [0, 36], [6, 0], [44, 0], [0, -10], [-12, 0], [0, 64], [0, -12], [12, 0], [-10, 0], [0, 38], [18, 0], [0, -18], [0, 36], [56, 0], [58, 0], [-6, 0], [0, -8], [0, 60], [-44, 0], [0, 6], [30, 0], [0, 62], [-36, 0], [0, -14], [-8, 0], [74, 0], [-6, 0], [0, 52], [0, 72], [46, 0], [0, 6], [-24, 0], [-30, 0], [0, 12], [56, 0], [0, -32], [70, 0], [0, -18], [36, 0], [0, 20], [-36, 0], [4, 0], [0, 12], [0, 32], [6, 0], [0, 42], [10, 0], [0, 6], [12, 0], [38, 0], [0, 8], [0, -12], [0, 14], [0, 46], [0, 12], [4, 0], [0, -44], [0, -18], [4, 0], [-36, 0], [-30, 0], [0, -44], [0, -30], [50, 0], [0, -28], [0, -14], [58, 0], [0, -70], [0, -20], [0, -12], [-80, 0], [-46, 0], [60, 0], [0, 0], [20, 0], [0, 12], [-28, 0], [0, 68], [6, 0], [0, -14], [0, 54], [28, 0], [30, 0], [-48, 0], [0, 24], [0, 6], [-36, 0], [0, -44], [-18, 0], [-76, 0], [0, 72], [60, 0], [0, -40], [0, 10], [0, 18], [46, 0]]