Here is an integral
NIntegrate[1/(px^2 + py^2 + 1)/((px - qx)^2 + (px - qy)^2 +
1)/(qx^2 + qy^2 + 1), {px, 0, 10}, {py, 0, 10}, {qx, 0, 10}, {qy, 0, 10}]
the integrant are all sufficiently small, but still MMA give a result and say the integral coverage too slow. I tried different method, none of them works. I could not understand what causes it? How to modify the code?
This works well.
NIntegrate[1/(px^2 + py^2 + 1)/((px - qx)^2 + (px - qy)^2 + 1)/(qx^2 + qy^2 + 1),
{px, 0, 10}, {py, 0, 10}, {qx, 0, 10}, {qy, 0, 10},Method -> "CartesianRule"] // Timing
{58.875, 2.84714}
Lowering the precision goal slightly from 6 to 5 (perhaps advisable in a high-dimensional integral) and increasing MinRecursion avoids both the NIntegrate::slwcon and NIntegrate::eincr warnings:
NIntegrate[
1/(px^2 + py^2 + 1)/((px - qx)^2 + (px - qy)^2 + 1)/(qx^2 + qy^2 + 1),
{px, 0, 10}, {py, 0, 10}, {qx, 0, 10}, {qy, 0, 10},
PrecisionGoal -> 5,
MinRecursion -> 1] // AbsoluteTiming
(* {5.563214`, 2.8471463223061835`} *)
Update: Alternative
FWIW, you can do an expensive (i.e., takes time) symbolic integration on one or two of the variables, followed by a numerical integration. E.g, integrating over {py, 0, 10} symbolically first takes about as long as the above and needs no other special numerical processing. The numerical advantage here is reducing the dimension of the integral. (In fact, if you integrate over qx and then py, then the two-dimensional integral is quite fast and unproblematic; however, the symbolic integration takes about 17 seconds.)
NIntegrate[
Evaluate@Integrate[
1/(px^2 + py^2 + 1)/((px - qx)^2 + (px - qy)^2 + 1)/(qx^2 + qy^2 + 1),
{py, 0, 10},
Assumptions -> 0 < px < 10 && 0 < py < 10 && 0 < qx < 10 && 0 < qy < 10]
, {px, 0, 10}, {qx, 0, 10}, {qy, 0, 10}] // AbsoluteTiming
(* {4.173041`, 2.8471449687848587`} *)
We also get the extra digit of accuracy @user64494 got.
Update 2: Third try, inspired by Mariusz Iwaniuk
There is a slight "spike" in the value of the integrand near the subspace px == qx == qy. This might be why NIntegrate has trouble getting the error estimate to satisfy precision goals of 6 or more. Some weak evidence is that feeding the subspace as an "Exclusion" with the "LocalAdaptive" method to NIntegrate gives a fairly quick solution agreeing with the other solutions to slightly more than six digits.
NIntegrate[
1/(px^2 + py^2 + 1)/((px - qx)^2 + (px - qy)^2 + 1)/(qx^2 + qy^2 + 1),
{px, 0, 10}, {py, 0, 10}, {qx, 0, 10}, {qy, 0, 10},
Method -> "LocalAdaptive", Exclusions -> {px == qx == qy}] // AbsoluteTiming
(* {3.497589`, 2.8471576198024686`} *)
AccuracyGoal sets a goal for the number of digits after the decimal point. When the result is 1, then Precision and Accuracy are the same. The corresponding AccuracyGoal for this integral would be about Accuracy[2.8471463223061835`5] or 4.54559. (The precision and accuracy goals combine, so that the absolute error estimate should be less than the sum of the errors implied by the two goals, and the correspondence is not quite as simple as I describe.)
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Commented
Jul 21, 2017 at 14:51
About a 1 second.
NIntegrate[
1/(px^2 + py^2 + 1)/((px - qx)^2 + (px - qy)^2 + 1)/(qx^2 + qy^2 + 1),
{px, 0, 10}, {py, 0, 10}, {qx, 0, 10}, {qy, 0, 10},
Method -> {"LocalAdaptive", "SymbolicProcessing" -> 0}] // Timing
(*{1.45313, 2.84718}*)
or:
NIntegrate[1/(px^2 + py^2 + 1)/((px - qx)^2 + (px - qy)^2 + 1)/(qx^2 + qy^2 +
1), {px, 0, 10}, {py, 0, 10}, {qx, 0, 10}, {qy, 0, 10},
PrecisionGoal -> 5, MinRecursion -> 1, Method -> {"LocalAdaptive",
"SymbolicProcessing" -> 0}] // AbsoluteTiming
(*{0.687526, 2.84731}*)
PrecisionGoal to get a comparable quality result, and then it's not really faster (or so it seems to me).
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Commented
Jul 21, 2017 at 17:42
NIntegrate::slwconif there are no other errors. (So you left out an important component of the question. You also left out the error message names, which are helpful to include because then people with similar problems can search the site for them.) $\endgroup$