Method and system for exhaust gas recirculation and heat recovery

The invention claimed is: 1. An engine method, comprising: flowing a first portion of exhaust into an upstream exhaust catalyst via a heat exchanger in a bypass passage; flowing a second, remaining portion of exhaust into the upstream exhaust catalyst via a main exhaust passage arranged parallel to the bypass passage; and adjusting fueling on a per-cylinder basis as a function of the first portion relative to the second portion to provide a target exhaust air-fuel-ratio at the upstream exhaust catalyst, wherein the adjusting fueling on the per-cylinder basis is based on a transport delay of the first portion of exhaust through the bypass passage relative to a transport delay of the second portion of exhaust through the main exhaust passage. 2. The method of claim 1 , further comprising combining the first portion and the second portion of exhaust at the upstream catalyst, and flowing the combined exhaust through the upstream exhaust catalyst and then through a downstream exhaust catalyst. 3. The method of claim 2 , wherein the flowing is responsive to each of the upstream exhaust catalyst exceeding a first activation temperature and the downstream exhaust catalyst exceeding a second activation temperature, and wherein the first portion is selected to maintain each of the upstream exhaust catalyst at or above the first activation temperature and the downstream exhaust catalyst at or above the second activation temperature. 4. The method of claim 3 , further comprising, responsive to at least the upstream exhaust catalyst being below the first activation temperature, flowing an entire volume of exhaust to the upstream exhaust catalyst while bypassing the heat exchanger. 5. The method of claim 3 , wherein the first portion is decreased and the second portion is correspondingly increased as a temperature of at least the upstream exhaust catalyst decreases. 6. The method of claim 1 , wherein flowing the first portion and the second portion includes actuating a diverter valve coupled at a junction of the main exhaust passage and an outlet of the bypass passage to an open position to enable exhaust flow from an exhaust bypass to the main exhaust passage, a degree of opening of the diverter valve increased as the first portion increases relative to the second portion. 7. The method of claim 6 , further comprising, during a request for exhaust gas recirculation (EGR), actuating the diverter valve to a fully closed position to disable exhaust flow from the exhaust bypass to the main exhaust passage, and opening an EGR valve to flow a third portion of exhaust to an engine intake manifold via an EGR delivery passage coupled to the exhaust bypass, downstream of the heat exchanger, and a fourth portion of exhaust directly to the upstream exhaust catalyst. 8. The method of claim 7 , wherein a ratio of the third portion to the fourth portion is adjusted based on each of EGR demand and a temperature of at least the upstream exhaust catalyst, the third portion is decreased and the fourth portion is correspondingly increased as the temperature of at least the upstream exhaust catalyst decreases, an opening of the EGR valve adjusted based on the third portion. 9. The method of claim 1 , wherein the adjusting fueling on the per-cylinder basis is based on input from each of a first oxygen sensor positioned upstream of the heat exchanger in the main exhaust passage and a second oxygen sensor positioned downstream of the heat exchanger in the main exhaust passage. 10. The method of claim 1 , wherein the target exhaust air-fuel-ratio at the upstream exhaust catalyst includes a target air-fuel-ratio perturbation at the upstream exhaust catalyst. 11. The method of claim 10 , wherein the first portion of exhaust includes exhaust received at a first timing from a first group of cylinders and wherein the second portion of exhaust includes exhaust received at a second timing from a second, different group of cylinders, and wherein when the target air-fuel-ratio perturbation at the upstream exhaust catalyst includes a rich air-fuel-ratio perturbation, fueling the first group of cylinders to be richer than stoichiometry and fueling the second group of cylinders to be leaner than stoichiometry, a degree of richness of the first group of cylinders higher than a degree of leanness of the second group of cylinders. 12. The method of claim 1 , wherein an engine is coupled in a vehicle having a cabin, the method further comprising: transferring heat from the first portion of exhaust to coolant flowing through the heat exchanger; and flowing heated coolant through an engine block and a heater core to heat the engine based on an engine heating demand and heat the cabin based on a cabin heating demand. 13. An engine system comprising: an engine intake manifold; an engine exhaust system with an exhaust passage and a heat exchange system, the exhaust passage including an exhaust humidity sensor, an exhaust temperature sensor, an exhaust pressure sensor, one or more exhaust catalysts, and a muffler, a bypass passage coupled to the exhaust passage from upstream of the one or more exhaust catalysts to upstream of the muffler, the heat exchange system including the bypass passage housing a heat exchanger; a coolant system fluidly coupled to the heat exchanger, an engine block, and a heater core, the coolant system including an engine coolant temperature sensor; a diverter valve coupling an outlet of the bypass passage to the exhaust passage; an exhaust gas recirculation (EGR) passage with an EGR valve for recirculating exhaust from the bypass passage, downstream of the heat exchanger, to the engine intake manifold; a first oxygen sensor coupled to the exhaust passage upstream of the heat exchanger and a second oxygen sensor coupled to the exhaust passage downstream of the heat exchanger; and a controller with computer readable instructions stored on non-transitory memory for: estimating engine temperature via the engine coolant temperature sensor and catalyst temperature via the exhaust temperature sensor, and, in response to a lower than threshold catalyst temperature, closing each of the EGR valve and the diverter valve to flow exhaust directly to the one or more exhaust catalysts; and in response to a higher than threshold catalyst temperature and a lower than threshold engine temperature, opening the diverter valve to flow a first amount of exhaust from an exhaust manifold to the one or more exhaust catalysts via the heat exchanger while flowing a second, remaining amount of exhaust directly to the one or more exhaust catalysts, bypassing the heat exchanger. 14. The system of claim 13 , wherein the controller contains further instructions for: estimating a first exhaust air-fuel-ratio based on input from the first oxygen sensor, estimating a second air-fuel-ratio based on input from the second oxygen sensor, and adjusting a cylinder-to-cylinder air-fuel-ratio based on each of the first air-fuel-ratio and the second air-fuel-ratio to maintain a target amplitude and frequency of air-fuel-ratio perturbation in the exhaust reaching the one or more exhaust catalysts, the adjusting including operating a first group of cylinders richer than stoichiometry while operating a second group of cylinders leaner than stoichiometry, wherein a degree of richness of the first group of cylinders and a degree of leanness of the second group of cylinders is based on the target amplitude and frequency of the air-fuel-ratio perturbation. 15. The system of claim 13 , wherein the controller includes further instructions for: in response to a request for EGR, opening the EGR valve