{
unsigned result = 0;
symbol x;
-
+
ex myseries = series(tgamma(x),x==0,order);
// compute the last coefficient numerically:
ex last_coeff = myseries.coeff(x,order-1).evalf();
// compute a bound for that coefficient using a variation of the leading
// term in Stirling's formula:
- ex bound = evalf(exp(ex(-.57721566490153286*(order-1)))/(order-1));
- if (evalf(abs((last_coeff-pow(-1,order))/bound)) > numeric(1)) {
+ ex bound = exp(-.57721566490153286*(order-1))/(order-1);
+ if (abs((last_coeff-pow(-1,order))/bound) > 1) {
clog << "The " << order-1
<< "th order coefficient in the power series expansion of tgamma(0) was erroneously found to be "
<< last_coeff << ", violating a simple estimate." << endl;
++result;
}
-
+
return result;
}
unsigned time_gammaseries(void)
{
unsigned result = 0;
-
+
cout << "timing Laurent series expansion of Gamma function" << flush;
clog << "-------Laurent series expansion of Gamma function:" << endl;
-
+
vector<unsigned> sizes;
vector<double> times;
timer omega;
-
+
sizes.push_back(10);
sizes.push_back(15);
sizes.push_back(20);
sizes.push_back(25);
-
+
for (vector<unsigned>::iterator i=sizes.begin(); i!=sizes.end(); ++i) {
omega.start();
result += tgammaseries(*i);
times.push_back(omega.read());
cout << '.' << flush;
}
-
+
if (!result) {
cout << " passed ";
clog << "(no output)" << endl;
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