Logic for improved delta pressure based soot estimation on low restriction particulate filters

What is claimed is: 1. A vehicle having an exhaust system implementing delta pressure based estimation of accumulated soot within a diesel particulate filter, comprising: an engine connected to an exhaust system, the exhaust system having therein a diesel oxidation catalyst and a diesel particulate filter; a fuel injector device connected to the exhaust system upstream from the diesel oxidation catalyst and the diesel particulate filter; a delta exhaust pressure sensor arrangement configured to measure a difference in exhaust pressure at an inlet to the diesel particulate filter and at an outlet to the diesel particulate filter; and at least one controller connected to the fuel injector and to the delta exhaust pressure sensor arrangement, and being configured to: 1.) determine when to conduct an active regeneration of the diesel particulate filter based on an estimated amount of soot accumulated therein; 2.) in a first regeneration mode, cause the fuel injector device to inject fuel at a first rate into the exhaust stream, and re-evaluate amount of soot accumulated within the diesel particulate filter under increased volumetric flow of the exhaust stream; and 3.) in a second regeneration mode, cause the fuel injector device to inject fuel at a second rate into the exhaust stream in order to combust soot trapped in the diesel particulate filter. 2. The vehicle of claim 1 , wherein: the at least one controller being further configured to at least one of: re-evaluate the amount of soot accumulated within the diesel particulate filter during the first regeneration mode to ensure the soot estimation is accurate; compare the re-evaluated amount of soot from the first regeneration mode with an initial estimated amount of soot; and further refine a correlation between diesel particulate filter delta pressure readings under operating conditions, and actual accumulation of soot as determined during the first regeneration mode. 3. The vehicle of claim 2 , wherein: the at least one controller being connected to at least one temperature sensor positioned at least one of: subsequent to the fuel injection device but prior to the diesel oxidation catalyst, subsequent to the diesel oxidation catalyst but prior to the diesel particulate filter, and subsequent to the diesel particulate filter. 4. The vehicle of claim 3 , wherein: the at least one controller being further configured to, when in the first regeneration mode, cause the fuel injector device to inject fuel into the exhaust stream at the first rate calculated to enter the diesel oxidation catalyst and favorably occupy catalytic reaction sites therein to reduce NO occupancy of the same sites, and to reduce the amount of NO that is oxidized to NO 2 , while increasing exhaust temperature and volumetric flow. 5. The vehicle of claim 3 , wherein: the first rate at which the fuel injection device injects fuel into the exhaust stream during the first regeneration mode being from five percent to ninety-five percent of the second rate at which the fuel injection device injects fuel into the exhaust stream during the second regeneration mode, provided that the first rate is not sufficient to combust\the soot trapped on the diesel particulate filter. 6. The vehicle of claim 3 , wherein: the at least one controller is at least one of: a vehicle control unit or module, an engine control unit or module, and an exhaust aftertreatment control unit or module. 7. The vehicle of claim 3 , wherein: the at least one controller being further configured to use recursive machine learning in refining the correlation between diesel particulate filter delta pressure readings under operating conditions, under increased exhaust temperature and volumetric exhaust flow during the first regeneration mode, and actual accumulation of soot within the diesel particulate filter.