What is a numbers converter?

A numbers converter helps you convert between different units of numbers quickly and accurately.

How do I convert base-31 to base-16?

Simply enter the value in the base-31 input field, and the converter will show you the equivalent value in base-16 instantly.

Is this numbers converter free to use?

Yes, this numbers converter is completely free and easy to use for all your conversion needs.

Can I switch between base-31 and base-16 easily?

Yes, there is a switch button provided to quickly swap the conversion direction between base-31 and base-16.

How accurate are the conversion results?

The conversion results are calculated using precise formulas to ensure accuracy for most practical purposes.

Convert base-31 to base-16 Online | Free numbers Converter

31 Number System

The base-31 number system, also called the untrigesimal system, is a positional numeral system that uses thirty-one symbols: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, A, B, C, D, E, F, G, H, I, J, K, L, M, N, O, P, Q, R, S, and T, where A represents ten, B eleven, C twelve, D thirteen, E fourteen, F fifteen, G sixteen, H seventeen, I eighteen, J nineteen, K twenty, L twenty-one, M twenty-two, N twenty-three, O twenty-four, P twenty-five, Q twenty-six, R twenty-seven, S twenty-eight, and T twenty-nine in decimal. Each digit’s position represents a power of 31, starting from $31^0$ at the rightmost digit and increasing to the left. For example, the base-31 number 3T7 equals $3 \times 31^2 + 29 \times 31^1 + 7 \times 31^0 = 2883 + 899 + 7 = 3789$ in decimal. Base-31 is primarily used in theoretical mathematics, number theory, and educational exercises to explore alternative numeral systems, positional notation, and arithmetic patterns. Understanding base-31 allows learners to perform arithmetic operations, convert numbers between bases, and analyze properties of non-decimal systems. Although rarely used in computing or daily life, studying the untrigesimal system enhances logical reasoning, problem-solving skills, and comprehension of abstract number representations. It also provides a foundation for higher-level numeral systems and theoretical mathematics.

Number System

The base-16 number system, also known as the hexadecimal system, is a positional numeral system that uses sixteen symbols: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, A, B, C, D, E, and F, where A represents ten, B eleven, C twelve, D thirteen, E fourteen, and F fifteen in decimal. Each digit’s position represents a power of 16, starting from $16^0$ at the rightmost digit and increasing to the left. For example, the hexadecimal number 2F3 equals $2 \times 16^2 + 15 \times 16^1 + 3 \times 16^0 = 512 + 240 + 3 = 755$ in decimal. Hexadecimal is widely used in computing and digital electronics because it provides a compact way to represent binary numbers, with each hex digit corresponding exactly to four binary digits. This simplifies conversions between binary and hexadecimal and makes it easier to read and write large binary values. Hexadecimal numbers are commonly used in programming, memory addressing, color codes in web design, and digital circuit design. Understanding base-16 is essential for computer scientists, engineers, and programmers, as it bridges the gap between human-readable numbers and machine-level binary code, enabling efficient computation, debugging, and data representation.