Composition Series Finder Calculator

Calculator Input

This calculator is designed for finite abelian groups written as products of cyclic factors, such as C₁₂ × C₁₈ × C₂₀.

Group label

Optional. Used in the result summary.

Cyclic factors

Enter integers greater than 1, separated by commas, spaces, or line breaks.

Reduction strategy

This changes the displayed chain order, not the multiset of composition factors.

Display preference

Sort subgroup factors before displaying them

Useful when you want a cleaner, standardized chain presentation.

Accepted scope

Finite abelian groups expressed by cyclic factors

General nonabelian group computation is outside this single-file calculator’s scope.

Output summary

Orders, composition factors, subgroup chain, CSV, PDF, and graph

The result appears above this form after submission.

Reset

Example Data Table

These examples illustrate how the calculator interprets finite abelian groups and counts prime-order composition factors.

Input cyclic factors	Group notation	Group order	Composition length	One possible factor multiset
12, 18	C₁₂ × C₁₈	216	6	C₂, C₂, C₂, C₃, C₃, C₃
8, 9	C₈ × C₉	72	5	C₂, C₂, C₂, C₃, C₃
4, 6, 10	C₄ × C₆ × C₁₀	240	6	C₂, C₂, C₂, C₂, C₃, C₅
27	C₂₇	27	3	C₃, C₃, C₃

Formula Used

This calculator uses the finite abelian group decomposition entered through cyclic factors.

G ≅ C_n1 × C_n2 × ... × C_nk

Each input factor n_i is factorized into primes. If n_i = ∏ p^a, then the total number of prime factors with multiplicity contributes to the composition length.

Length L(G) = Ω(n1) + Ω(n2) + ... + Ω(nk)

Here, Ω(n) means the total number of prime factors of n, counting repeated primes.

|G| = n1 × n2 × ... × nk

The subgroup order drops by one prime factor at every step of the chain.

|G_r| = |G_r-1| / p_r

Every quotient G_r-1 / G_r is a simple cyclic group of prime order, written as C_p.

How to Use This Calculator

Enter the cyclic factors of your finite abelian group, such as 12, 18, 20.
Choose a reduction strategy. It changes the displayed chain order only.
Select the display sorting option when you want subgroup factors shown in increasing order.
Press Find Composition Series.
Read the summary cards for order, length, and factor counts.
Inspect the composition factor badges and the subgroup chain table.
Use the Plotly graph to follow subgroup order through each prime reduction.
Export the result using the CSV or PDF buttons.

FAQs

1) What kind of groups does this calculator support?

It supports finite abelian groups entered as products of cyclic factors, such as C12 × C18 × C20. It does not attempt general nonabelian composition-series computation.

2) Why are the composition factors always prime-order cyclic groups?

For finite abelian groups, simple quotient groups must be cyclic of prime order. That is why every displayed composition factor has the form C_p.

3) What does the composition length mean?

It is the number of simple factors in the composition series. In this calculator, it equals the total count of prime factors, with multiplicity, across all input cyclic orders.

4) Why can different strategies produce different chains?

Different strategies remove prime divisors in different orders. The actual chain may vary, but the multiset of composition factors remains the same by the Jordan–Hölder theorem.

5) Does sorting subgroup factors change the mathematics?

No. Sorting affects display only. It simply rewrites the direct-product factors in a cleaner order for reading, exporting, and comparing results.

6) Can I enter repeated cyclic factors?

Yes. Repeated values are fully valid. For example, entering 4, 4, 9 represents C4 × C4 × C9, and the calculator handles each component separately.

7) What does the graph show?

The Plotly graph shows the subgroup order after each reduction step. It helps you visualize how the chain descends from the whole group to the trivial subgroup.

8) Why is this useful for teaching or revision?

It connects decomposition, subgroup chains, quotient simplicity, and prime factorization in one place. That makes examples faster to verify and easier to explain.