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Week 2/3 1.System interconnections (block diagrams) 2.Finite State Machines (Chapter 3)
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Recall
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A system S is a function : InputSignals OutputSignals with InputSignals = [D R], OutputSignals = [D’ R’] S x InputSignals y = S(x) OutputSignals
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10Evans: [Ints + {enter, leave}] [Ints + Integers + ] 10Evans u = (e,l,l,e,e,… ) y = (6,5,4,5,6,… ) initial number in room 5 InputSignals OutputSignals
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The system 10Evans can be specified as follows: y = 10Evans (u), and for all n Ints +, y(n) is given by where
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How do you ‘give’ S? S u Speeds y=S(u) Positions Speeds = [[0,5] Reals], Positions = [[0,5] Reals] y(0) initial position
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Other examples: TopicNotes/Systems/DTMFTopicNotes/Systems/DTMF KeypadSequences Sounds DTMF DTMF: [Nats KeypadSymbols] [Time Pressure]
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Interconnecting Systems: Block Diagrams
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Voice [Time Pressure]; MicOutput [Time Volts] Microphone: [Time Pressure] [Time Volts]; AGCSound [Time Pressure]; Volume [Time Volts] VolumeSensor: [Time Pressure] [Time Volts]; Output [Time Volts] AGC: [Time Volts] x [Time Volts] [Time Pressure] v 1 = Microphone (u) s = AGC (v 1, v 2 ) v 2 = VolumeSensor(s) y = v 2 MicOutput AGCSound Microphone AGC Volume Sensor Voice uv1v1 s v2v2 Output y 4 equations 4 unknowns
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Finite State Machines
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Recognizer x = (x(0), x(1), x(2), …) y = (y(0), y(1), y(2), …) x InputSignals = [Nats 0 {0,1}] y OutputSignals = [Nats 0 {t,f}] x InputSignals y OutputSignals Recognizer(x)(n) = t, if (x(n-2),x(n-1),x(n)) = (0,0,0) = f, else Recognizer((0,1,0,0,0,0,1,1, …)) = (f,f,f,f,t,t,f,f, …)
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init a b 0/f 0/t 1/f x InputSignals y OutputSignals x = (0, 1, 0, 0, 0, 0, 1, 1, …) s = (init, a, init, a, b, b, b, init, …) y = (f, f, f, f, t, t, f, f, …) s(0) = init (s(n+1), y(n)) = update (s(n), x(n)), n = 0,1,…
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init a b {0}/f {0}/t {1,2}/f x [Nats 0 {0,1,2}] y [Nats 0 {t,f}] x = (0, 2, 0, 0, 0, 0, 1, 2, …) s = (init, a, init, a, b, b, b, init, …) y = (f, f, f, f, f, t, t, f, …) s(0) = init (s(n+1), y(n)) = update (s(n), x(n)), n = 0,1,… guard
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What does this machine with 4 states do? ‘1,2’ ‘0’ ’00’ {0}/f {0}/t {1,2}/f y [Nats 0 {t,f}] init {0}/f {1,2}/f x [Nats 0 {0,1,2}] It also implements Recognizer Can a machine with 2 states implement Recognizer?
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Formal definition of state machine 1.Sets and functions 2.Bubble and arcs 3.Tabular
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A state machine is a 5-tuple StateMachine = (States, Inputs, Outputs, update, initialState) States is the state space Inputs is the input alphabet Outputs is the output alphabet initialState States is the initial state update: States x Inputs States x Outputs is the update function Sets and function
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For Recognizer States = {init, a, b} Inputs = {0,1} Outputs = {t, f} initialState = init update(init, 0) = (0, f) update(init, 1) = (init, f) … update: States x Inputs States x Outputs is given by: current state current input next state current output (s(n+1), y(n)) = update(s(n), x(n))
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It is useful sometimes to express the update function as two functions: update = (nextState, output), nextState: States x Inputs States output: States x Inputs Outputs so that update(s(n), x(n)) = (s(n+1), y(n)) nextState(s(n), x(n)) = s(n+1) output(s(n), x(n)) = y(n)
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Operation of state machine Given S = (States, Inputs, Outputs, update, initialState) InputSignals = [Nats 0 Inputs] OutputSignals = [Nats 0 Outputs] An input signal x = (x(0), x(1), …, x(n), …) determines the state response s: Nats 0 States and the output signal y: Nats 0 Outputs by the recursion, s(0) = initState, and n 0, (s(n+1), y(n)) = update (s(n), x(n)) Thus S determines an input-output function (system) F: InputSignals OutputSignals
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For Recognizer InputSignals = [Nats 0 {0,1}] OutputSignals = [Nats 0 {t,f}] The input-output function (system) is F: x InputSignals, n Nats 0 y(n) = F(x)(n) = t, if (x(n-2), x(n-1)), x(0)) = (0,0,0) = f, else
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Stuttering
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It is useful to introduce a stuttering symbol absent We insist that absent Inputs and absent Outputs We require that for all states s States update(s, absent) = (s, absent)
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A modified Recognizer init a b 0/abs 0/t 1/abs x InputSignals y OutputSignals x = (0, 1, 0, 0, 0, 0, 1, 1, …) s = (init, a, init, a, b, b, b, init, …) y = (abs, abs, abs, abs, t, t, abs, abs, …)
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Bubbles and arcs
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Shorthand: the ‘else’ loop init a b {0}/abs else x [Nats 0 {0,1,2, absent}] y [Nats 0 {t,absent}] else 0/t
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Shorthand: the implicit ‘else’ self loop init a b {0}/abs else x [Nats 0 {0,1,2, absent}] y [Nats 0 {t,absent}] else 0/t
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Shorthand: the implicit ‘absent’ init a b {0}/ else x [Nats 0 {0,1,2, absent}] y [Nats 0 {t,absent}] else 0/t abs
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The guards are subsets of Inputs guards on different arcs from same state are disjoint (determinism) union of all guards (from same state) = Inputs; (reactive system) guard on ‘else’ is complement of remaining guards guards may be defined using convenient notation, eg. if Inputs = {a, b, c}, a = {b,c}
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Tabular Representation
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All information about a state machine is given its update function. If States and Inputs are finite, update can be given as a table (next state, output) if input is current state init a b 01absent (a, f) (b, f) (b, t) (init, f) (init, abs) (a, abs) (b, abs)
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System requirements in English System specification as F: InputSignals OutputSignals System implementation as state machine Described by set-and-functions 5-tuple, transition diagram, or table State machine design process
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60-min Parking meter {tick, coin5, coin25, absent} {safe, expired, absent} Parking meter topics/state/parking meter
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Answering machine topics/state/answering machine table
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