To provide the binary representation for "a," we first need to know that "a" is a character in the ASCII (American Standard Code for Information Interchange) encoding system. In ASCII, the character "a" is represented by the decimal value 97, which converts to binary as 01100001. Thus, the binary representation for "a" is 01100001.
The binary representation of the decimal number 0.125 can be found by converting it to binary. Since 0.125 is equal to ( \frac{1}{8} ), it can be expressed as ( 0.001 ) in binary. This is derived from the fact that ( 2^{-3} = 0.125 ). Thus, the binary representation of 0.125 is ( 0.001 ).
11111111=255 'o' zeroes are present in the binary representation of 51x5
The hexadecimal value 0xCA can be converted to binary by converting each hex digit to its 4-bit binary equivalent. The hex digit 'C' corresponds to the binary 1100, and 'A' corresponds to 1010. Therefore, the binary representation of 0xCA is 11001010.
1310 = 11012
That is the binary representation of the decimal number 105.
The binary representation is : 1111011001
The binary representation of the keyword "129" in decimal is 10000001.
I am not!
11111111=255 'o' zeroes are present in the binary representation of 51x5
The hexadecimal value 0xCA can be converted to binary by converting each hex digit to its 4-bit binary equivalent. The hex digit 'C' corresponds to the binary 1100, and 'A' corresponds to 1010. Therefore, the binary representation of 0xCA is 11001010.
4 = 100
1310 = 11012
Binary code is not a device. It is a numerical representation of data.
That is the binary representation of the decimal number 105.
It is 101010111100.
1010 = 10102
the answer is 25, it is quite easy