Systems and methods for determining crankshaft position based indicated mean effective pressure (IMEP)

What is claimed is: 1. A system for a vehicle, comprising: a first electronic circuit that generates engine speeds based on positions of teeth of a toothed wheel that rotates with a crankshaft of an engine and based on a crankshaft position signal generated by a crankshaft position sensor, wherein the crankshaft position sensor generates the crankshaft position signal based on rotation of the toothed wheel; and a second electronic circuit that generates an indicated work for a combustion cycle of a cylinder of the engine based on squares of first and second ones of the engine speeds; a third electronic circuit that generates an indicated mean effective pressure (IMEP) for the combustion cycle of the cylinder based on the indicated work and a displacement volume of the engine; and at least one of: a fourth electronic circuit that selectively adjusts fueling of a future combustion cycle of the cylinder based on the IMEP; a fifth electronic circuit that selectively adjusts spark timing of the future combustion cycle of the cylinder based on the IMEP; a sixth electronic circuit that selectively adjusts throttle opening based on the IMEP; and a seventh electronic that selectively adjusts opening of at least one of an intake valve and an exhaust valve of the cylinder based on the IMEP. 2. The system of claim 1 wherein the second electronic circuit sets the indicated work using the equation: W=ω e 2 −ω s 2 where W is the indicated work, ω e is the first one of the engine speeds at a first predetermined crankshaft position of the expansion stroke of the combustion cycle of the cylinder, ω s is the second one of the engine speeds at a second predetermined crankshaft position of the combustion cycle, and the first predetermined crankshaft position is later in the combustion cycle than the second predetermined crankshaft position. 3. The system of claim 1 wherein the second electronic circuit sets the indicated work using the equation: W=p *(ω e 2 −ω s 2 )+ q where W is the indicated work, ω e is the first one of the engine speeds at a first predetermined crankshaft position of the expansion stroke of the combustion cycle of the cylinder, ω s is the second one of the engine speeds at a second predetermined crankshaft position of the combustion cycle, p is a predetermined gain, q is a predetermined offset, and the first predetermined crankshaft position is later in the combustion cycle than the second predetermined crankshaft position. 4. The system of claim 1 wherein the second electronic circuit sets the indicated work using the equation: W =(ω e 2 −ω s 2 )+(ω y 2 −ω x 2 ) where W is the indicated work, ω e is the first one of the engine speeds at a first predetermined crankshaft position of the expansion stroke of the combustion cycle of the cylinder, ω s is the second one of the engine speeds at a second predetermined crankshaft position of the expansion stroke, ω y is a third one of the engine speeds at a third predetermined crankshaft position of the compression stroke of the combustion cycle of the cylinder, ω x is a fourth one of the engine speeds at a fourth predetermined crankshaft position of the compression stroke, the first predetermined crankshaft position is later in the expansion stroke than the second predetermined crankshaft position, and the fourth predetermined crankshaft position is later in the compression stroke than the third predetermined crankshaft position. 5. The system of claim 1 wherein the second electronic circuit sets the indicated work using the equation: W=p (ω e 2 −ω s 2 )+ q *(ω y 2 −ω x 2 )+ r where W is the indicated work, ω e is the first one of the engine speeds at a first predetermined crankshaft position of the expansion stroke of the combustion cycle of the cylinder, ω s is the second one of the engine speeds at a second predetermined crankshaft position of the expansion stroke, ω y is a third one of the engine speeds at a third predetermined crankshaft position of the compression stroke of the combustion cycle of the cylinder, ω x is a fourth one of the engine speeds at a fourth predetermined crankshaft position of the compression stroke, p and q are first and second predetermined gains, respectively, r is a predetermined offset, the first predetermined crankshaft position is later in the expansion stroke than the second predetermined crankshaft position, and the fourth predetermined crankshaft position is later in the compression stroke than the third predetermined crankshaft position. 6. The system of claim 1 wherein the second electronic circuit sets the indicated work using the equation: W=p*ω p 2 +q*ω q 2 +r*ω r 2 +s*ω s 2 +t*ω t 2 +u*ω u 2 +v where W is the indicated work, ω p , ω q , ω r , ω s , ω t , and ω u are first, second, third, fourth, fifth, and sixth ones of the engine speeds at first, second, third, fourth, fifth, and sixth predetermined crankshaft positions of the combustion cycle of the cylinder, respectively, p, q, r, s, t, and u are first, second, third, fourth, fifth, and sixth predetermined gains, and v is a predetermined offset. 7. The system of claim 1 further comprising an eighth electronic circuit that detects the occurrence of misfire within the cylinder based on the IMEP. 8. The system of claim 1 further comprising an eighth electronic circuit that diagnoses the presence of a fault in the vehicle based on the IMEP. 9. The system of claim 1 wherein the first, second, and third electronic circuits include at least one of: an Application Specific Integrated Circuit (ASIC); a combinational logic circuit; a field programmable gate array (FPGA); and a processor and memory including code that is executed by the processor.