Diagnostic test for engine exhaust system

What is claimed is: 1. A vehicle controller programmed to, in response to a command to perform a diagnostic test: operate an engine under a first lean condition at a commanded air-fuel ratio to decrease an oxygen storage capacity of a catalytic converter from a set value to an adjusted value that is greater than zero; determine an actual air-fuel ratio based on measuring an oxygen content within exhaust gas entering the catalytic converter via a first sensor, while the engine is operating under the first lean condition; and in response to a difference between the actual air-fuel ratio and the commanded air-fuel ratio being less a first tolerance from zero and a change in the oxygen content within the exhaust gas exiting the catalytic converter, that is measured via a second sensor, being less than a second tolerance from zero, while the engine is operating under the first lean condition, register that the first sensor and the catalytic converter are functioning properly. 2. The controller of claim 1 , wherein the controller is further programmed to: operate the engine under a second lean condition, after operating the engine under the first lean condition, to decrease the oxygen storage capacity of the catalytic converter from the adjusted value toward zero; and in response to detecting an increase in the oxygen content within the exhaust gas exiting the catalytic converter coinciding with the oxygen storage capacity decreasing to a value within a third tolerance from zero, while the engine is operating under the second lean condition, register that the second sensor is functioning properly. 3. The controller of claim 2 , wherein the controller is further programmed to, while the engine is operating under the second lean condition, in response to not detecting an increase in the oxygen content within the exhaust gas exiting the catalytic converter when with the oxygen storage capacity of the catalytic converter decreases to zero, register that the second sensor has malfunctioned. 4. The controller of claim 2 , wherein the oxygen storage capacity is decreased from the adjusted value towards zero in incremental steps during the second lean condition. 5. The controller of claim 2 , wherein the controller is further programmed to, while the engine is operating under the second lean condition: in response to detecting an increase in the oxygen content within the exhaust gas exiting the catalytic converter coinciding with the oxygen storage capacity decreasing to a value within the third tolerance from zero, adjust a zero point of the oxygen storage capacity. 6. The controller of claim 2 , wherein the controller is further programmed to, operate the engine under a rich condition, after operating the engine under the second lean condition, to increase the oxygen storage capacity of the catalytic converter to the set value. 7. The controller of claim 1 , wherein the controller is further programmed to, while the engine is operating under the first lean condition: in response to the difference between the actual air-fuel ratio and the commanded air-fuel ratio exceeding the first tolerance from zero or the change in the oxygen content within the exhaust gas exiting the catalytic converter exceeding the second tolerance from zero, register that the first sensor and/or the catalytic converter have malfunctioned. 8. A vehicle controller programmed to, in response to a command to perform a diagnostic test: operate an engine under a first rich condition at a commanded air-fuel ratio to increase an oxygen storage capacity of a catalytic converter from a set value to an adjusted value; determine an actual air-fuel ratio based on measuring an oxygen content within exhaust gas entering the catalytic converter via a first sensor, while the engine is operating under the first rich condition; and in response to a difference between the actual air-fuel ratio and the commanded air-fuel ratio being less a first tolerance from zero and a change in the oxygen content within the exhaust gas exiting the catalytic converter, that is measured via a second sensor, being less than a second tolerance from zero, while the engine is operating under the first rich condition, register that the first sensor and the catalytic converter are functioning properly. 9. The controller of claim 8 , wherein the controller is further programmed to: operate the engine under a second rich condition, after operating the engine under the first rich condition, to increase the oxygen storage capacity of the catalytic converter from the adjusted value toward a maximum value; and in response to detecting a decrease in the oxygen content within the exhaust gas exiting the catalytic converter coinciding with the oxygen storage capacity increasing to a value within a third tolerance from the maximum value, register that the second sensor is functioning properly. 10. The controller of claim 9 , wherein the controller is further programmed to, while the engine is operating under the second rich condition, in response to not detecting a decrease in the oxygen content within the exhaust gas exiting the catalytic converter when with the oxygen storage capacity of the catalytic converter increases to the maximum value, register that the second sensor has malfunctioned. 11. The controller of claim 9 , wherein the oxygen storage capacity is increased from the adjusted value towards the maximum value in incremental steps during the second rich condition. 12. The controller of claim 9 , wherein the controller is further programmed to, while the engine is operating under the second rich condition: in response to detecting a decrease in the oxygen content within the exhaust gas exiting the catalytic converter coinciding with the oxygen storage capacity increasing to a value within the third tolerance from the maximum value, adjust a maximum value point of the oxygen storage capacity. 13. The controller of claim 9 , wherein the controller is further programmed to, operate the engine under a lean condition, after operating the engine under the second rich condition, to decrease the oxygen storage capacity of the catalytic converter to the set value. 14. The controller of claim 8 , wherein the controller is further programmed to, while the engine is operating under the first rich condition: in response to the difference between the actual air-fuel ratio and the commanded air-fuel ratio exceeding the first tolerance from zero or the change in the oxygen content within the exhaust gas exiting the catalytic converter exceeding the second tolerance from zero, register that the first sensor and/or the catalytic converter have malfunctioned. 15. A vehicle controller programmed to, in response to a command to perform a diagnostic test: operate an engine under a first lean condition at a first commanded air-fuel ratio to decrease an oxygen storage capacity of a catalytic converter from a set value to an adjusted value; determine an actual air-fuel ratio based on measuring an oxygen content within exhaust gas entering the catalytic converter via a first sensor, while the engine is operating under the first lean condition; operate the engine under a first rich condition at a second commanded air-fuel ratio to increase the oxygen storage capacity of the catalytic converter from the set value to a second adjusted value; determine the actual air-fuel ratio based on measuring the oxygen content within exhaust gas entering the catalytic converter via the first sensor, while the engine is operating under the first rich condition; and in response to a difference between the actual air-fue