This article discusses the design of control system components for gasoline engines. Gasoline or, more precisely, spark ignition engines power a large majority of personal vehicles sold worldwide. A major task for the automakers is to provide good drivability and fuel economy while meeting increasingly stringent emission requirements. Achieving low emissions requires a significant reduction in cold start emissions and employment of catalytic converters to reduce tailpipe emissions once the engine is warmed up. The catalysts are loaded with precious metals – typically platinum, palladium, and rhodium. They achieve very high conversion efficiencies, but only if the engine is operated very close to stoichiometry that corresponds to the air-fuel ratio of about 14.6 for gasoline and of 9 for ethanol. Design of a control system component requires that an appropriate model be developed. The models range from very simple low-order, linear for the inner loop to a partial-differential-equation based model for the catalyst. In general, feedback controllers tolerate and even benefit from simpler models. Feed-forward control, estimation, diagnostics, and failure mode management requires more elaborate models.

1.
D.
Hrovat
,
M.
Jankovic
,
I.
Kolmanovsky
,
S.
Magner
,
D.
Yanakiev
, “Powertrain Control,” in Control Handbook: Control System Applications, 2nd edition,
W.
Levin
editor,
CRC Press
, Dec.
2010
.
2.
M.
Santillo
,
S.
Magner
,
M.
Uhrich
,
M.
Jankovic
,
“Towards ECU executable control oriented models of a three way catalytic converter,”
Proceedings of DSCC
,
Columbus OH
, Oct.
2015
.
3.
M.
Jankovic
,
D.
Hagner
,
“Twin-model method for ethanol detection in flex fuel vehicles,”
American Control Conference
,
Washington DC
, June,
2013
.
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