Below, I have written an answer for `n`

equals to 5, but you can apply same approach to draw DFAs for any value of `n`

and 'any positional number system' e.g binary, ternary...

First lean the term 'Complete DFA', A DFA defined on complete domain in δ:Q × Σ→Q is called 'Complete DFA'. In other words we can say; in transition diagram of complete DFA there is no missing edge (e.g. from each state in Q there is one outgoing edge present for every language symbol in Σ). Note: Sometime we define partial DFA as δ ⊆ Q × Σ→Q (Read: How does “δ:Q × Σ→Q” read in the definition of a DFA).

## Design DFA accepting Binary numbers divisible by number 'n':

**Step-1**: When you divide a number ω by `n`

then reminder can be either 0, 1, ..., (n - 2) or (n - 1). If remainder is `0`

that means ω is divisible by `n`

otherwise not. So, in my DFA there will be a state q_{r} that would be corresponding to a remainder value `r`

, where `0 <= r <= (n - 1)`

, and total number of states in DFA is `n`

.

After processing a number string ω over Σ, the end state is q_{r} implies that ω % n => r (% reminder operator).

In any automata, the purpose of a state is like memory element. A state in an atomata stores some information like fan's switch that can tell whether the fan is in 'off' or in 'on' state. For n = 5, five states in DFA corresponding to five reminder information as follows:

- State q
_{0} reached if reminder is 0. State q_{0} is the final state(accepting state). It is also an initial state.
- State q
_{1} reaches if reminder is 1, a non-final state.
- State q
_{2} if reminder is 2, a non-final state.
- State q
_{3} if reminder is 3, a non-final state.
- State q
_{4} if reminder is 4, a non-final state.

Using above information, we can start drawing transition diagram TD of five states as follows:

**Figure-1**

So, 5 states for 5 remainder values. After processing a string ω if end-state becomes q_{0} that means decimal equivalent of input string is divisible by 5. In above figure q_{0} is marked final state as two concentric circle.

Additionally, I have defined a transition rule δ:(q_{0}, 0)→q_{0} as a self loop for symbol `'0'`

at state q_{0}, this is because decimal equivalent of any string consist of only `'0'`

is 0 and 0 is a divisible by `n`

.

**Step-2**: TD above is incomplete; and can only process strings of `'0'`

s. Now add some more edges so that it can process subsequent number's strings. Check table below, shows new transition rules those can be added next step:

┌──────┬──────┬─────────────┬─────────┐
│**Number**│**Binary**│**Remainder(%5)**│**End-state**│
├──────┼──────┼─────────────┼─────────┤
│One │1 │1 │q_{1} │
├──────┼──────┼─────────────┼─────────┤
│Two │10 │2 │q_{2} │
├──────┼──────┼─────────────┼─────────┤
│Three │11 │3 │q_{3} │
├──────┼──────┼─────────────┼─────────┤
│Four │100 │4 │q_{4} │
└──────┴──────┴─────────────┴─────────┘

- To process binary string
`'1'`

there should be a transition rule δ:(q_{0}, 1)→q_{1}
- Two:- binary representation is
`'10'`

, end-state should be q_{2}, and to process `'10'`

, we just need to add one more transition rule δ:(q_{1}, 0)→q_{2}

**Path**: →(q_{0})─1→(q_{1})─0→(q_{2})
- Three:- in binary it is
`'11'`

, end-state is q_{3}, and we need to add a transition rule δ:(q_{1}, 1)→q_{3}

**Path**: →(q_{0})─1→(q_{1})─1→(q_{3})
- Four:- in binary
`'100'`

, end-state is q_{4}. TD already processes prefix string `'10'`

and we just need to add a new transition rule δ:(q_{2}, 0)→q_{4}

**Path**: →(q_{0})─1→(q_{1})─0→(q_{2})─0→(q_{4})

**Figure-2**

**Step-3**: Five = 101

Above transition diagram in figure-2 is still incomplete and there are many missing edges, for an example no transition is defined for δ:(q_{2}, 1)-**?**. And the rule should be present to process strings like `'101'`

.

Because `'101'`

= 5 is divisible by 5, and to accept `'101'`

I will add δ:(q_{2}, 1)→q_{0} in above figure-2.

**Path:** →(q_{0})─1→(q_{1})─0→(q_{2})─1→(q_{0})

with this new rule, transition diagram becomes as follows:

**Figure-3**

Below in each step I pick next subsequent binary number to add a missing edge until I get TD as a 'complete DFA'.

**Step-4**: Six = 110.

We can process `'11'`

in present TD in figure-3 as: →(q_{0})─11→(q_{3}) ─0→(**?**). Because 6 % 5 = 1 this means to add one rule δ:(q_{3}, 0)→q_{1}.

**Figure-4**

**Step-5**: Seven = 111

┌──────┬──────┬─────────────┬─────────┬────────────┬───────────┐
│**Number**│**Binary**│**Remainder(%5)**│**End-state**│** Path** │ **Add** │
├──────┼──────┼─────────────┼─────────┼────────────┼───────────┤
│Seven │111 │7 % 5 = 2 │q_{2} │ q_{0}─11→q_{3} **│** q_{3}─1→q_{2} │
└──────┴──────┴─────────────┴─────────┴────────────┴───────────┘

**Figure-5**

**Step-6**: Eight = 1000

┌──────┬──────┬─────────────┬─────────┬──────────┬─────────┐
│**Number**│**Binary**│**Remainder(%5)**│**End-state**│** Path** │ **Add** │
├──────┼──────┼─────────────┼─────────┼──────────┼─────────┤
│Eight │1000 │8 % 5 = 3 │q_{3} │q_{0}─100→q_{4} │ q_{4}─0→q_{3} │
└──────┴──────┴─────────────┴─────────┴──────────┴─────────┘

**Figure-6**

**Step-7**: Nine = 1001

┌──────┬──────┬─────────────┬─────────┬──────────┬─────────┐
│**Number**│**Binary**│**Remainder(%5)**│**End-state**│** Path** │ **Add** │
├──────┼──────┼─────────────┼─────────┼──────────┼─────────┤
│Nine │1001 │9 % 5 = 4 │q_{4} │q_{0}─100→q_{4} │ q_{4}─1→q_{4} │
└──────┴──────┴─────────────┴─────────┴──────────┴─────────┘

**Figure-7**

In TD-7, total number of edges are 10 == Q × Σ = 5 × 2. And it is a complete DFA that can accept all possible binary strings those decimal equivalent is divisible by 5.

## Design DFA accepting Ternary numbers divisible by number n:

**Step-1** Exactly same as for binary, use figure-1.

**Step-2** Add Zero, One, Two

┌───────┬───────┬─────────────┬─────────┬──────────────┐
│**Decimal**│**Ternary**│**Remainder(%5)**│**End-state**│** Add** │
├───────┼───────┼─────────────┼─────────┼──────────────┤
│Zero │0 │0 │q0 │ δ:(q0,0)→q0 │
├───────┼───────┼─────────────┼─────────┼──────────────┤
│One │1 │1 │q1 │ δ:(q0,1)→q1 │
├───────┼───────┼─────────────┼─────────┼──────────────┤
│Two │2 │2 │q2 │ δ:(q0,2)→q3 │
└───────┴───────┴─────────────┴─────────┴──────────────┘

**Figure-8**

**Step-3** Add Three, Four, Five

┌───────┬───────┬─────────────┬─────────┬─────────────┐
│**Decimal**│**Ternary**│**Remainder(%5)**│**End-state**│ **Add** │
├───────┼───────┼─────────────┼─────────┼─────────────┤
│Three │10 │3 │q3 │ δ:(q1,0)→q3 │
├───────┼───────┼─────────────┼─────────┼─────────────┤
│Four │11 │4 │q4 │ δ:(q1,1)→q4 │
├───────┼───────┼─────────────┼─────────┼─────────────┤
│Five │12 │0 │q0 │ δ:(q1,2)→q0 │
└───────┴───────┴─────────────┴─────────┴─────────────┘

**Figure-9**

**Step-4** Add Six, Seven, Eight

┌───────┬───────┬─────────────┬─────────┬─────────────┐
│**Decimal**│**Ternary**│**Remainder(%5)**│**End-state**│ **Add** │
├───────┼───────┼─────────────┼─────────┼─────────────┤
│Six │20 │1 │q1 │ δ:(q2,0)→q1 │
├───────┼───────┼─────────────┼─────────┼─────────────┤
│Seven │21 │2 │q2 │ δ:(q2,1)→q2 │
├───────┼───────┼─────────────┼─────────┼─────────────┤
│Eight │22 │3 │q3 │ δ:(q2,2)→q3 │
└───────┴───────┴─────────────┴─────────┴─────────────┘

**Figure-10**

**Step-5** Add Nine, Ten, Eleven

┌───────┬───────┬─────────────┬─────────┬─────────────┐
│**Decimal**│**Ternary**│**Remainder(%5)**│**End-state**│ **Add** │
├───────┼───────┼─────────────┼─────────┼─────────────┤
│Nine │100 │4 │q4 │ δ:(q3,0)→q4 │
├───────┼───────┼─────────────┼─────────┼─────────────┤
│Ten │101 │0 │q0 │ δ:(q3,1)→q0 │
├───────┼───────┼─────────────┼─────────┼─────────────┤
│Eleven │102 │1 │q1 │ δ:(q3,2)→q1 │
└───────┴───────┴─────────────┴─────────┴─────────────┘

**Figure-11**

**Step-6** Add Twelve, Thirteen, Fourteen

┌────────┬───────┬─────────────┬─────────┬─────────────┐
│**Decimal** │**Ternary**│**Remainder(%5)**│**End-state**│ **Add** │
├────────┼───────┼─────────────┼─────────┼─────────────┤
│Twelve │110 │2 │q2 │ δ:(q4,0)→q2 │
├────────┼───────┼─────────────┼─────────┼─────────────┤
│Thirteen│111 │3 │q3 │ δ:(q4,1)→q3 │
├────────┼───────┼─────────────┼─────────┼─────────────┤
│Fourteen│112 │4 │q4 │ δ:(q4,2)→q4 │
└────────┴───────┴─────────────┴─────────┴─────────────┘

**Figure-12**

Total number of edges in transition diagram figure-12 are 15 = Q × Σ = 5 * 3 (a complete DFA). And this DFA can accept all strings consist over {0, 1, 2} those decimal equivalent is divisible by 5.

If you notice at each step, in table there are three entries because at each step I add all possible outgoing edge from a state to make a complete DFA (and I add an edge so that q_{r} state gets for remainder is `r`

)!

To add further, remember union of two regular languages are also a regular. If you need to design a DFA that accepts binary strings those decimal equivalent is either divisible by 3 or 5, then draw two separate DFAs for divisible by 3 and 5 then union both DFAs to construct target DFA (for 1 <= n <= 10 your have to union 10 DFAs).

If you are asked to draw DFA that accepts binary strings such that decimal equivalent is divisible by 5 and 3 both then you are looking for DFA of divisible by 15 ( but what about 6 and 8?).

Note: DFAs drawn with this technique will be minimized DFA only when there is *no* common factor between number `n`

and base e.g. there is *no* between 5 and 2 in first example, or between 5 and 3 in second example, hence both DFAs constructed above are minimized DFAs. If you are interested to read further about possible mini states for number `n`

and base `b`

read paper: Divisibility and State Complexity.

^{ below I have added a Python script, I written it for fun while learning Python library pygraphviz. I am adding it I hope it can be helpful for someone in someway.}

## Design DFA for base 'b' number strings divisible by number 'n':

So we can apply above trick to draw DFA to recognize number strings in any base `'b'`

those are divisible a given number `'n'`

. In that DFA total number of states will be `n`

(for `n`

remainders) and number of edges should be equal to 'b' * 'n' — that is complete DFA: 'b' = number of symbols in language of DFA and 'n' = number of states.

Using above trick, below I have written a Python Script to Draw DFA for input `base`

and `number`

. In script, function `divided_by_N`

populates DFA's transition rules in `base * number`

steps. In each step-num, I convert `num`

into number string `num_s`

using function `baseN()`

. To avoid processing each number string, I have used a temporary data-structure `lookup_table`

. In each step, end-state for number string `num_s`

is evaluated and stored in `lookup_table`

to use in next step.

For transition graph of DFA, I have written a function `draw_transition_graph`

using Pygraphviz library (very easy to use). To use this script you need to install `graphviz`

. To add colorful edges in transition diagram, I randomly generates color codes for each symbol `get_color_dict`

function.

```
#!/usr/bin/env python
import pygraphviz as pgv
from pprint import pprint
from random import choice as rchoice
def baseN(n, b, syms="0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ"):
""" converts a number `n` into base `b` string """
return ((n == 0) and syms[0]) or (
baseN(n//b, b, syms).lstrip(syms[0]) + syms[n % b])
def divided_by_N(number, base):
"""
constructs DFA that accepts given `base` number strings
those are divisible by a given `number`
"""
ACCEPTING_STATE = START_STATE = '0'
SYMBOL_0 = '0'
dfa = {
str(from_state): {
str(symbol): 'to_state' for symbol in range(base)
}
for from_state in range(number)
}
dfa[START_STATE][SYMBOL_0] = ACCEPTING_STATE
# `lookup_table` keeps track: 'number string' -->[dfa]--> 'end_state'
lookup_table = { SYMBOL_0: ACCEPTING_STATE }.setdefault
for num in range(number * base):
end_state = str(num % number)
num_s = baseN(num, base)
before_end_state = lookup_table(num_s[:-1], START_STATE)
dfa[before_end_state][num_s[-1]] = end_state
lookup_table(num_s, end_state)
return dfa
def symcolrhexcodes(symbols):
"""
returns dict of color codes mapped with alphabets symbol in symbols
"""
return {
symbol: '#'+''.join([
rchoice("8A6C2B590D1F4E37") for _ in "FFFFFF"
])
for symbol in symbols
}
def draw_transition_graph(dfa, filename="filename"):
ACCEPTING_STATE = START_STATE = '0'
colors = symcolrhexcodes(dfa[START_STATE].keys())
# draw transition graph
tg = pgv.AGraph(strict=False, directed=True, decorate=True)
for from_state in dfa:
for symbol, to_state in dfa[from_state].iteritems():
tg.add_edge("Q%s"%from_state, "Q%s"%to_state,
label=symbol, color=colors[symbol],
fontcolor=colors[symbol])
# add intial edge from an invisible node!
tg.add_node('null', shape='plaintext', label='start')
tg.add_edge('null', "Q%s"%START_STATE,)
# make end acception state as 'doublecircle'
tg.get_node("Q%s"%ACCEPTING_STATE).attr['shape'] = 'doublecircle'
tg.draw(filename, prog='circo')
tg.close()
def print_transition_table(dfa):
print("DFA accepting number string in base '%(base)s' "
"those are divisible by '%(number)s':" % {
'base': len(dfa['0']),
'number': len(dfa),})
pprint(dfa)
if __name__ == "__main__":
number = input ("Enter NUMBER: ")
base = input ("Enter BASE of number system: ")
dfa = divided_by_N(number, base)
print_transition_table(dfa)
draw_transition_graph(dfa)
```

**Execute it:**

```
~/study/divide-5/script$ python script.py
Enter NUMBER: 5
Enter BASE of number system: 4
DFA accepting number string in base '4' those are divisible by '5':
{'0': {'0': '0', '1': '1', '2': '2', '3': '3'},
'1': {'0': '4', '1': '0', '2': '1', '3': '2'},
'2': {'0': '3', '1': '4', '2': '0', '3': '1'},
'3': {'0': '2', '1': '3', '2': '4', '3': '0'},
'4': {'0': '1', '1': '2', '2': '3', '3': '4'}}
~/study/divide-5/script$ ls
script.py filename.png
~/study/divide-5/script$ display filename
```

**Output:**

**DFA accepting number strings in base 4 those are divisible by 5**

Similarly, enter base = 4 and number = 7 to generate - dfa accepting number string in base '4' those are divisible by '7'

Btw, try changing `filename`

to `.png`

or `.jpeg`

.

_{
References those I use to write this script:
➊ Function baseN from "convert integer to a string in a given numeric base in python"
➋ To install "pygraphviz": "Python does not see pygraphviz"
➌ To learn use of Pygraphviz: "Python-FSM"
➍ To generate random hex color codes for each language symbol: "How would I make a random hexdigit code generator using .join and for loops?"
}

`n`

it is trivial, right? – akonsu Feb 20 '14 at 3:49`n`

must have`log(n)`

trailing zeros. – akonsu Feb 20 '14 at 4:09