Air handling control for opposed-piston engines with uniflow scavenging

The invention claimed is: 1. A uniflow-scavenged, opposed-piston engine equipped with an air handling system, comprising: at feast one cylinder with a bore, axially-spaced exhaust and intake ports, and a pair of pistons disposed in opposition in the bore and operative to open and close the exhaust and intake ports during operation of the opposed-piston engine; a charge air channel to provide charge air to the intake port; an exhaust channel to receive exhaust gas from the exhaust port; a supercharger operable to pump charge air in the charge air channel; and, a control mechanization operable to determine a trapped lambda value of a mass of charge air trapped in the cylinder by the last port of the cylinder to close, in response to an engine operating state, and to adjust, based on the determined trapped lambda value, charge air flow in the charge air channel. 2. The opposed-piston engine of claim 1 , in which the control mechanization is operable to adjust charge air flow based on the determined trapped lambda value by one of changing a speed of the supercharger and operating a first valve to shunt charge air flow from an output to an input of the supercharger. 3. The opposed-piston engine of claim 1 , in which the engine includes an exhaust gas recirculation (EGR) loop having a loop input coupled to the exhaust channel and a loop output coupled to the charge air channel and the control mechanism is further operable to determine a trapped burned gas fraction value of a mass of combustion gases that are trapped in the cylinder trapped in the cylinder by the last port of the cylinder to close, in response to the engine operating state and to adjust, based on the determined value of the trapped burned gas fraction, EGR flow in the EGR loop. 4. The opposed-piston engine of claim 3 , in which the control mechanization is operable to: adjust charge air flow based on the determined value of trapped lambda by one of changing a speed of the supercharger and operating a first valve to shunt charge air flow from an output to an input of the supercharger; and adjust EGR flow based on the determined value of trapped burned gas fraction by operating a second valve to increase or decrease exhaust gas flow through the EGR loop. 5. The opposed-piston engine of claim 4 , in which the control mechanization is operable to: calculate an actual trapped lambda parameter value based on the current engine operating state; determine a desired trapped lambda parameter value for the current engine operating state; determine an error value based upon a difference between the actual and desired lambda parameter values; and, adjust charge air flow by one of changing a fresh air flow into the charge air channel or changing an intake manifold pressure in response to the error value. 6. The opposed-piston engine of claim 1 , in which the control mechanization is operable to: calculate an actual trapped lambda parameter value based on the current engine operating state; determine a desired trapped lambda parameter value for the current engine operating state; determine an error value based upon a difference between the actual and desired lambda parameter values; and, adjust charge air flow by one of changing a fresh air mass flow rate into the charge air channel or changing an intake manifold pressure in response to the error value. 7. An opposed-piston engine, comprising: at least one cylinder with a bore, axially-spaced exhaust and intake ports, and a pair of pistons disposed in opposition in the bore and operative to open and close the exhaust and intake ports during operation of the engine; a charge air channel to provide charge air to the intake port; an exhaust channel to receive exhaust gas from the exhaust port; a supercharger operable to pump charge air in the charge air channel; and, a control mechanization operable to: determine a trapped lambda value of a mass of charge air trapped in the cylinder by the last port of the cylinder to close, in response to an engine operating state; and to adjust, based on the determined trapped lambda value, a flow of air provided to an inlet of the supercharger and a pressure of charge air pumped to the intake port. 8. The opposed-piston engine of claim 7 , in which the control mechanization is operable to: calculate an actual trapped lambda parameter value based on the engine operating state; determine a desired trapped lambda parameter value for the engine operating state; determine an error value based upon a difference between the actual and desired lambda parameter values; and, adjust the speed of the supercharger in response to the error value; or adjust the state of a valve coupling an output of the supercharger to an input of the supercharger. 9. An opposed-piston engine, comprising: at least one cylinder with a bore, axially-spaced exhaust and intake ports, and a pair of pistons disposed in opposition in the bore and operative to open and close the exhaust and intake ports during operation of the engine; a charge air channel to provide charge air to the intake port; an exhaust channel to receive exhaust gas from the exhaust port; an exhaust gas recirculation (EGR) loop having a loop input coupled to the exhaust channel and a loop output coupled to the charge air channel; a supercharger operable to pump charge air in the charge air channel; a valve in the EGR loop operable to regulate a flow of exhaust gas to the charge air channel; and, a control mechanization operable to: determine a trapped burned gas fraction value of a mass of combustion gases that are trapped in the cylinder trapped in the cylinder by the last port of the cylinder to close, in response to an engine operating state; and to adjust, based on the determined trapped burned gas fraction value, a flow of exhaust gas through the EGR loop. 10. The opposed-piston engine of claim 9 , in which the control mechanization is operable to: calculate an actual trapped burned gas fraction parameter value based on the engine operating state; determine a desired trapped burned gas fraction parameter value for the engine operating state; determine an error value based upon a difference between the actual and desired lambda burned gas fraction values; and, adjust the setting of the valve in response to the error value.