LXXIII in Roman Numerals

Ancient Romans discovered that counting fingers could get very complicated after 10. So to overcome the complexity, the Roman numeric system was developed. This was widely used throughout Europe as a standard writing system until the late Middle Ages.

Seven symbols are used to represent numbers in the Roman numeric system — I, V, X, L, C, D, and M. The numerals are made up of different combinations of these symbols. LXXIII in Roman numerals can be written in number form by adding the values of each Roman numeral, i.e., LXXIII = 73.

Let us learn more about the Roman numeral LXXIII, how we write them, the mistakes we usually make, and ways to avoid these mistakes.

When writing Roman numerals, there are a few rules that we need to follow based on the Roman numerals we are trying to write. In this section, we will learn about the rules when writing Roman numerals and how to represent them.

Rule 1: Addition Method:

When a larger symbol is followed by a smaller symbol, we add the numerals to each other. For example, in VIII, we have 5 + 3 = 8.

Rule 2: Repetition Method:

A symbol that is repeated three times in continuation increases the value of the numeral. For example, XXX = 30.

Rule 3: Subtraction Method:

We use the subtraction method when a larger symbol follows a smaller symbol. For example, XL = 40 (which is 50 – 10).

Rule 4: Limitation Rule:

Symbols cannot be repeated more than three times, and some symbols, such as V, L, and D, cannot be repeated more than once. For example, 10 is represented as X and not VV.

Let us learn about how to write LXXIII in Roman numerals. There are two methods that we can use to write Roman numerals:

• By Expansion Method
• By Grouping Method

The breaking down of Roman numerals into parts and then converting them into numerals is what we call the expansion method. The expansion method is the breaking down of Roman numerals into numerical form and adding them to get the final number.

Step 1: Break the Roman numerals into parts.

Step 2: Now write each of the Roman numerals with its numerical digit in the place value.

Step 3: Add the numerals together.

For LXXIII,

Step 1: First, we break the Roman numerals. LXXIII = L + X + X + I + I + I

Step 2: Write the Roman Numerals for each part The Roman Numeral L is 50 The Roman Numeral X is 10 The Roman Numeral I is 1

Step 3: Combine all the numbers L + X + X + I + I + I = 50 + 10 + 10 + 1 + 1 + 1 = 73. Therefore, the Roman Numeral LXXIII is 73.

Using subtraction and addition rules, we will apply the grouping method. This means we break the Roman numerals into smaller groups, which makes it easier to work with. This method groups the Roman numerals logically, and then we write the numbers for each group.

Step 1: Take the largest number and write the number for that Roman numeral.

Step 2: Write the Roman numeral using the subtraction and addition rules.

Example: Let’s take the Roman numeral LXXIII.

Step 1: The larger Roman numerals are what we will begin with. Once split, the Roman numerals we get are L, XX, and III. The numeral for L is 50 The numeral for XX is 20

Step 2: Now we need to either add or subtract the smaller number, depending on its place. Here we add III to LXX and we will get LXXIII. The Roman numeral III is 3 Therefore, the numeral of LXXIII is 73.

We follow a pattern when it comes to writing Roman numerals. In this section, we will write some numbers related to the Roman numeral LXXIII: 

• Limitation Rule: There are some symbols that cannot be repeated more than once (V, L, D). For example, LVV for 60 is wrong; the correct answer is LX.
   
• Place Value: The position of a digit in a number; this position determines its value. For example, the number 7 in 73 is in the ten's place.
   
• Subtraction Method: A method used in Roman numerals where a smaller numeral placed before a larger one is subtracted. For example, IX is 9.
   
• Addition Method: A method where numerals are added together when a larger symbol precedes a smaller one. For example, VI is 6.
   
• Prime Number: A number that has only two factors or multiples is called a prime number. For example, 73 is a prime number that has only two factors, 1 and itself.