Method for optimizing anti-collision and latency for PEPS passive response

What is claimed is: 1. A method for authenticating a passive entry, passive start system having a plurality of remote fobs each having a functional transmitter ID comprising: (a) interrogating the plurality of remote fobs with a body control module; (b) issuing a first signal from at least one first remote fob in a first time slot when an ID number is an even number and in response to an interrogation signal from the body control module, wherein the at least one first remote fob is selected from the plurality of remote fobs, wherein the ID number is at least one bit in the functional transmitter ID; (c) issuing a second signal from at least one second remote fob in a second time slot when the ID number is an odd number and in response to the interrogation signal from the body control module, wherein the at least one second remote fob is selected from the plurality of remote fobs and the second time slot differs from the first time slot; (d) issuing a response signal from the plurality of remote fobs within at least one of a third time slot and a fourth time slot in response to the interrogation signal from the body control module, wherein the response signal in the at least one of the third time slot and fourth time slot is based on a random number generated by each of the plurality of remote fobs; (e) authenticating the at least one first remote fob with the body control module when the first signal and the response signal is received by the body control module in a free and clear state; (f) authenticating the at least one second remote fob with the body control module when the second signal and the response signal is received by the body control module in the free and clear state. 2. The method of claim 1 further comprising repeating (a)-(d) when neither the first signal nor the second signals are received by the body control module in the free and clear state. 3. The method of claim 1 further comprises issuing the first signal in the first time slot when the functional ID is an even number, and issuing the second signal in the second time slot when the functional ID is an odd number in response to a first interrogation. 4. The method of claim 3 wherein the plurality of remote fobs are repeatedly interrogated until one of the first signal and the second signal is received in the free and clear state. 5. The method of claim 3 further comprises issuing the first signal in the first time slot when a least significant bit functional ID is an even number, and issuing the second signal in the second time slot when the least significant bit is an odd number in response to a second interrogation. 6. The method of claim 5 further comprises issuing the first signal in the first time slot when a second least significant bit functional ID is an even number, and issuing the second signal in the second time slot when the second least significant bit is an odd number in response to a third interrogation. 7. The method of claim 1 further comprising issuing the response signal from the plurality of remote fobs within the third time slot and the fourth time slot in response to the interrogation signal from the body control module, wherein the response signal is based on a random number generated by each of the plurality of remote fobs. 8. A method for authenticating a passive entry, passive start system having a plurality of remote fobs each having a functional transmitter ID comprising: (a) interrogating the plurality of remote fobs with a body control module; (b) issuing a first signal from at least one first remote fob in a first time slot when the functional transmitter ID is an even number and in response to an interrogation signal from the body control module, wherein the at least one first remote fob is selected from the plurality of remote fobs; (c) issuing a second signal from at least one second remote fob in a second time slot when the functional transmitter ID is an odd number and in response to the interrogation signal from the body control module, wherein the at least one second remote fob is selected from the plurality of remote fobs and the second time slot differs from the first time slot; (d) issuing a response signal from the plurality of remote fobs within at least one of a third time slot and a fourth time slot in response to the interrogation signal from the body control module, wherein the response signal in the at least one of the third time slot and fourth time slot is based on a random number generated by each of the plurality of remote fobs; (e) authenticating the at least one first remote fob with the body control module when the first signal and the response signal is received by the body control module in a free and clear state; and (f) authenticating the at least one second remote fob with the body control module when the second signal and the response signal is received by the body control module in the free and clear state. 9. The method of claim 8 further comprising: (g) interrogating the plurality of remote fobs with the body control module when neither the first signal nor the second signals are received by the body control module in the free and clear state; (h) issuing a first signal from at least one first remote fob in a first time slot when a least significant bit of functional transmitter ID is an even number and in response to the interrogation signal from the body control module, wherein the at least one first remote fob is selected from the plurality of remote fobs; (i) issuing a second signal from at least one second remote fob in a second time slot when the least significant bit of the functional transmitter ID is an odd number and in response to the interrogation signal from the body control module, wherein the at least one second remote fob is selected from the plurality of remote fobs and the second time slot differs from the first time slot; (j) authenticating the at least one first remote fob with the body control module when the first signal and the response signal is received by the body control module in a free and clear state; and (k) authenticating the at least one second remote fob with the body control module when the second signal and the response signal is received by the body control module in the free and clear state. 10. The method of claim 9 further comprising: (l) interrogating the plurality of remote fobs with a body control module when neither the first signal nor the second signals are received by the body control module in the free and clear state; (m) issuing a first signal from at least one first remote fob in a first time slot when a second least significant bit of functional transmitter ID is an even number and in response to the interrogation signal from the body control module, wherein the at least one first remote fob is selected from the plurality of remote fobs; (n) issuing a second signal from at least one second remote fob in a second time slot when the second least significant bit of the functional transmitter ID is an odd number and in response to the interrogation signal from the body control module, wherein the at least one second remote fob is selected from the plurality of remote fobs and the second time slot differs from the first time slot; (o) authenticating the at least one first remote fob with the body control module when the first signal and the response signal is received by the body control module in a free and clear state; and (p) authenticating the at least one second remote fob with the body control module when the second signal and the response signal is received by the body control module in the free and clear state. 11. The method of claim 8 further comprising issuing the response signal f