Ammonia sensor control, with NOx feedback, of an SCR aftertreatment system

What is claimed is: 1. A method, comprising: determining an ammonia (NH 3 ) reference target comprising a target amount of NH 3 in an exhaust conduit between a first selective catalytic reduction (SCR) catalyst and a second SCR catalyst located in the exhaust conduit; determining a present amount of NH 3 in the exhaust conduit between the first SCR catalyst and the second SCR catalyst with an ammonia sensor; determining an NH 3 error term in response to the NH 3 reference target and the present amount of NH 3 ; determining a reductant doser command in response to the NH 3 error term; determining an amount of NO x downstream of the second SCR catalyst, and adjusting one of the NH 3 reference target and a reductant doser command in response to the amount of NO x downstream of the second SCR catalyst; and injecting, with a reductant injector, an amount of reductant in response to the adjusted one of the NH 3 reference target and the reductant doser command. 2. The method of claim 1 , further comprising determining a rate of change of the amount of NO x downstream of the second SCR catalyst, and further adjusting the one of the NH 3 reference target and the reductant doser command in response to the rate of change of the amount of NO x downstream of the second SCR catalyst. 3. The method of claim 1 , further determining an amount of NH 3 downstream of the second SCR catalyst, and further adjusting the one of the NH 3 reference target and the reductant doser command in response to the amount of NH 3 downstream of the second SCR catalyst. 4. The method of claim 3 , further comprising determining an adjusted downstream NO x amount by subtracting the amount of NH 3 downstream of the second SCR catalyst from the amount of NO x downstream of the second SCR catalyst, and further adjusting the one of the NH 3 reference target and the reductant doser command in response to the adjusted downstream NO x amount. 5. The method of claim 4 , further comprising determining an excess downstream NO x amount in response to the adjusted downstream NO x amount and a NO x reference target, and further adjusting the one of the NH 3 reference target and the reductant doser command in response to the excess downstream NO x amount. 6. An apparatus, comprising: an electronic controller operably connected to a reductant doser, the electronic controller including a plurality of modules that are implemented as at least one of hardware and instructions on a computer readable medium, the plurality of modules including: an ammonia (NH 3 ) target module structured to determine an NH 3 reference target comprising a target amount of NH 3 in an exhaust conduit between a first selective catalytic reduction (SCR) catalyst and a second SCR catalyst, wherein the NH 3 reference target is the target amount of NH 3 that occurs at a mid-bed position between the first SCR catalyst and the second SCR catalyst in response to injection of a targeted amount of reductant upstream of the first SCR catalyst; an NH 3 determination module structured to determine a present amount of NH 3 in the exhaust conduit between the first SCR catalyst and the second SCR catalyst in response to an output from an ammonia sensor that defines a separation point between the first SCR catalyst and the second SCR catalyst at the mid-bed position; NH 3 an error module structured to determine an NH 3 error term in response to the NH 3 reference target and the present amount of NH 3 ; a dosing control module structured to provide a reductant doser command in response to the NH 3 error term; and an outer loop control module structured to determine an amount of NO x downstream of the second SCR catalyst, and to adjust one of the NH 3 reference target and the reductant doser command in response to the amount of NO x downstream of the second SCR catalyst and control the reductant doser to inject reductant in response to the adjusted one of the NH 3 reference target and the reductant doser command. 7. The apparatus of claim 6 , further comprising an NH 3 time response adjustment module structured to determine at least one of a rate of change of the present amount of NH 3 and a rate of change of the amount of NO x downstream of the second SCR catalyst, and to further adjust the one of the NH 3 reference target and the reductant doser command in response to the at least one rate of change. 8. The apparatus of claim 6 , further comprising an NH 3 time response adjustment module structured to determine a product of a rate of change of the present amount of NH 3 and a rate of change of the amount of NO x downstream of the second SCR catalyst, and to further adjust the one of the NH 3 reference target and the reductant doser command in response to the product. 9. the apparatus of claim 8 , wherein the NH 3 time response adjustment module is further structured to determine a rate-based adjustment amount as a function of the product, and to further adjust the one of the NH 3 reference target and the reductant doser command in response to the rate-based adjustment amount. 10. The apparatus of claim 9 , wherein the NH 3 time response adjustment module is further structured to limit the rate-based adjustment amount to a proportion of an amount of NO x upstream of the first SCR catalyst. 11. The apparatus of claim 9 , wherein the function of the product comprises a non-linear function having a low gain in a negative region of the product and a high gain in a positive region of the product. 12. The apparatus of claim 6 , further comprising a NO x trimming module structured to determine an adjusted downstream NO x amount in response to the amount of NO x downstream of the second SCR catalyst and an amount of NH 3 downstream of the second SCR catalyst, and to further adjust the one of the NH 3 reference target and the reductant doser command in response to the adjusted downstream NO x amount. 13. The apparatus of claim 12 , wherein the NO x trimming module is further structured to determine an excess downstream NO x amount in response to the adjusted downstream NO x amount and a NO x reference target, and to further adjust the one of the NH 3 reference target and the reductant doser command in response to the excess downstream NO x amount. 14. A method, comprising: interpreting an NH 3 reference target comprising a target amount of NH 3 present at a mid-bed position between two selective catalytic reduction (SCR) catalysts, wherein the NH3 reference target is the target amount of NH 3 that occurs at a mid-bed position between the SCR catalysts in response to injection of a targeted amount of reductant upstream of the SCR catalysts; interpreting an amount of NO x downstream of the SCR catalysts and a present amount of NH 3 in the exhaust conduit between the SCR catalysts in response to an output from ammonia sensor that defines a separation point between the SCR catalysts at the mid-bed position; adjusting the NH 3 reference target in response to the amount of NO x downstream of the SCR catalysts, the present amount of NH 3 , and the NH 3 reference target; and injecting, with a reductant injector, an amount of urea upstream of the SCR catalysts in response to the adjusted NH 3 reference target. 15. The method of claim 14 , further comprising interpreting an amount of NH 3 downstream of the SCR catalysts, determining an adjusted amount of NO x downstream of the SCR catalysts in response to the amount of NH 3 downstream of the SCR catalysts, and wherein the adjusting is further in response to the adjusted amount of NO x downstream of the SCR