ETHZ/Intro Tim
From 2007.igem.org
.:: System Explanation ::.
The proposed system is best described by a [http://en.wikipedia.org/wiki/Mealy_machine Mealy machine], a special type of [http://en.wikipedia.org/wiki/Finite_state_machine finite state machines] (FSM). Mealy machines are defined by a 6-tuple, (Q, q0, Σ, Λ, δ, Ω), with:
- Q - a set of states, for the proposed system we use three different states (q0 - not yet trained, q1 - trained to recognize chemical A, q2 - trained to recognize chemical B)
- q0 - a start state, here we assume we start in a state where the system is not yet trained
- Σ = {A+L, A, B+L, B} - an input alphabet
- Λ = {green, red, blue, yellow} - an output alphabet
- δ : Q × Σ → Q - a state transition function
- Ω : Q × Σ → Λ - an output function
In detail, the transition function δ and the output function Ω look as follows:
inputs/states | q0 | q1 | q2 | inputs/states | q0 | q1 | q2 | |
---|---|---|---|---|---|---|---|---|
A+L | q1 | q1 | q1 | A+L | green | green | blue | |
A | q0 | q0 | q0 | A | green | green | green | |
B+L | q2 | q2 | q2 | B+L | yellow | red | yellow | |
B | q0 | q0 | q0 | B | yellow | yellow | yellow |
The resulting automaton is shown in Fig. 1.
In its native state (q0), the system reacts on the presence of either chemical A or B by fluorescing green or yellow, respectively. The system itself remains in the same state. Only when the input chemical is combined with a learning signal (chemical L), it changes its state either to q1 (in presence of chemical A) or q2 (in presence of chemical B).