Thompson (with capital T): 0101010001101000011011110110110101110000011100110110111101101110
The binary code contains an even number of 0s.
Morse code and binary code both encode and decode information, but they use different methods. Morse code uses combinations of dots and dashes to represent letters and numbers, while binary code uses combinations of 0s and 1s. Morse code relies on sound or light signals, while binary code is used in computers to represent data. Both codes require a key or chart to decode the information.
01001101011010010110101101100101
I wouldn't think so, since you can't really "fluently speak binary"
Binary code and Morse code are both systems used to represent information through a series of symbols. Binary code uses combinations of 0s and 1s to represent letters, numbers, and other characters in computers, while Morse code uses combinations of dots and dashes to represent the same information in telecommunication. Both codes serve as a way to encode and decode information, but they use different symbols and methods to do so.
Thompson (with capital T): 0101010001101000011011110110110101110000011100110110111101101110
Say
0100110101100001011100110110111101101110
110001010110000100100
01
01
01100111 01101111 01101111 01100100 01100010 01111001 01100101 = goodbye in binary
That IS the binary code.
That depends on your string encoding. In ascii, for example: H = 72 = 1001000 i = 105 = 1101001
To represent the name "Sam" in binary code, you need to convert each letter to its ASCII value and then to binary. The ASCII values for 'S', 'a', and 'm' are 83, 97, and 109, respectively. In binary, these values are represented as: 'S' = 01010011, 'a' = 01100001, and 'm' = 01101101. Therefore, "Sam" in binary code is 01010011 01100001 01101101.
00100001 is the binary code for 33
Jamesgates discovered binary code instringtheory