2014 ã. âïåðâûå â Ðîññèè â ÈÏÀ ÐÀÍ áûë ñîçäàí è èñïûòàí ïðîãðàììíûé êîððåëÿòîð äëÿ îáðàáîòêè íàáëþäåíèé ÐÑÄÁ-ñåòè ìàëûõ àíòåíí ñòàíäàðòà VGOS. Êîððåëÿòîð ïðåäíàçíà÷åí äëÿ îáðàáîòêè â ðåæèìå êâàçèðåàëüíîãî âðåìåíè øèðîêîïîëîñíûõ ÐÑÄÁ-íàáëþäåíèé 6 ñòàíöèé, 4 ÷àñòîòíûõ äèàïàçîíîâ è 2 ïîëÿðèçàöèé [1, 2].
 Ïðîãðàììíûé êîððåëÿòîð èìååò FX-àëãîðèòì êîððåëÿöèîííîé îáðàáîòêè ñèãíàëîâ è ôóíêöèîíèðóåò íà ïðîöåññîðíîì êëàñòåðå ãèáðèäíîé áëåéä-ñåðâåðíîé àðõèòåêòóðû, êðîìå ñòàíäàðòíûõ ïðîöåññîðîâ ñîäåðæàùåì ãðàôè÷åñêèå ïðîöåññîðíûå óñòðîéñòâà (ÃÏÓ) NVIDIA Tesla K20. Íàèáîëåå òðóäîåìêèå âû÷èñëåíèÿ ðåàëèçîâàíû íà ÃÏÓ.
 Âîçìîæíîñòè êîððåëÿòîðà áûëè ïðîâåðåíû è ïîäòâåðæäåíû â òåñòîâûõ èñïûòàíèÿõ — îáðàáîòêå ñìîäåëèðîâàííûõ è ðåàëüíûõ ÐÑÄÁ-äàííûõ. Êîððåëÿòîð áûë óñïåøíî ïðîòåñòèðîâàí íà ìàêñèìàëüíóþ ïðîèçâîäèòåëüíîñòü îáðàáîòêè äàííûõ, ó÷àñòâîâàë â èñïûòàíèÿõ íîâûõ ìàëûõ àíòåíí ÐÑÄÁ-êîìïëåêñà «Êâàçàð-ÊÂλ è îáðàáîòêå ïåðâûõ íàáëþäåíèé ýòèõ àíòåíí ïî îïðåäåëåíèþ Âñåìèðíîãî âðåìåíè UT1–UTC.

The first Russian software correlator for a new VGOS VLBI network was developed and tested in 2014. The correlator was designed to be capable of near-real time processing wideband VLBI observations from 6 stations, 4 frequency channels and 2 polarizations each. The RAS software correlator is based on the FX algorithm and implemented on a hybrid blade-server HPC cluster which contains Tesla K20 GPUs in addition to regular CPUs on each server blade. GPUs are used for the most time-consuming operations. The correlator was tested using simulated and real VLBI data. The tests with a maximal data rate were a success. The new correlator was used to process the VLBI data (UT1–UTC determined) received from the new 13-meter telescopes of the VLBI network «Quasar».