Unsigned.
It is the binary number 1010100. A binary number represents exponential values of 2, in this case 7 digits for 64, 32, 16, 8, 4, 2, and 1 84 = 64 + (0x32) + 16 + (0x8) +4 + (0x2) + (0x1) = 1010100
Positive. A negative number added to a positive would reduce the original to a smaller positive, to zero, or to a negative depending on their relative values but subtracting a negative number from a positive number will always increase the value of the positive.
The decimal number in binary is the six-digit number 110000. The digits in a binary number are exponents of 2 rather than 10, so that for a six-digit number in binary, the digit places represent 32, 16, 8, 4, 2, 1 instead of increasing values of 10. 110000 = 32 +16 + (0x8) + (0x4) + (0x2) + (0x1) = 48
The binary number 11011010 is the decimal number 218. The digits in a binary number are exponents of 2 rather than 10, so that for an eight-digit number in binary, the digit places represent 128, 64, 32, 16, 8, 4, 2, 1 instead of increasing values of 10. 11011010 = 128 + 64 + (0x32) +16 + 8 + (0x4) + 2 + (0x1) = 218
The number 68 in binary is the seven digit number 1000100. The digits in a binary number are exponents of 2 rather than 10, so that for a seven digit number in binary, the digit places represent 64, 32, 16, 8, 4, 2, 1 instead of increasing values of 10. 1000100 = 64+0+0+0+4+0+0 = 68
It is most commonly called an unsigned integer, but some programming languages have other terms for it.
The binary values is 10110101.
It is 1111.
The 'bc' command is a simple binary calculator (hence the name bc). It can do simple math and uses arbitrary precision arithmetic. You can designate the scaling, precision, and other values to use in math calculations. Arbitrary precision arithmetic allows you to exceed the hardware precision of the system you are on, by scaling to any number of significant digits that you may require.
That depends on the values of the given numbers but a positive number multiplied by a negative number will be negative
4 bits
Significant figures indicate the precision of a measurement.
24, or 16 (0 through 15) One binary digit (bit) can have 21 values (0 or 1). Two bits can have 22 values. Three bits can have 23 values. A five-bit number can have 25 values... and so on...
The number 23 is 10111 in binary. The digits in a binary number are exponents of 2 rather than 10, so that for a five digit number in binary, the digit places represent 16, 8, 4, 2, 1 instead of increasing values of 10. 10111 = 16+0+4+2+1 = 23
The binary number 1111 is 15. The digits in a binary number are exponents of 2 rather than 10, so that for a four digit number in binary, the digit places represent 8, 4, 2, 1 instead of increasing values of 10. 1111 = 8+4+2+1 = 15
Positive. A negative number added to a positive would reduce the original to a smaller positive, to zero, or to a negative depending on their relative values but subtracting a negative number from a positive number will always increase the value of the positive.
It is the binary number 1010100. A binary number represents exponential values of 2, in this case 7 digits for 64, 32, 16, 8, 4, 2, and 1 84 = 64 + (0x32) + 16 + (0x8) +4 + (0x2) + (0x1) = 1010100