A numeric constant may be a scalar, a vector, or a matrix, and it may contain complex values.
The simplest form of a numeric constant, a scalar, is a single number that can be an integer, a decimal fraction, a number in scientific (exponential) notation, or a complex number. Note that by default numeric constants are represented within Octave in double-precision floating point format (complex constants are stored as pairs of double-precision floating point values). It is, however, possible to represent real integers as described in Integer Data Types. Here are some examples of real-valued numeric constants, which all have the same value:
105 1.05e+2 1050e-1
To specify complex constants, you can write an expression of the form
3 + 4i 3.0 + 4.0i 0.3e1 + 40e-1i
all of which are equivalent. The letter ‘i’ in the previous example
stands for the pure imaginary constant, defined as
For Octave to recognize a value as the imaginary part of a complex constant, a space must not appear between the number and the ‘i’. If it does, Octave will print an error message, like this:
octave:13> 3 + 4 i parse error: syntax error >>> 3 + 4 i ^
You may also use ‘j’, ‘I’, or ‘J’ in place of the ‘i’ above. All four forms are equivalent.
Convert x to double precision type.
See also: single.
Return a complex value from real arguments.
With 1 real argument x, return the complex result
x + 0i.
With 2 real arguments, return the complex result
re + im.
complex can often be more convenient than expressions such as
a + i*b.
complex ([1, 2], [3, 4]) ⇒ [ 1 + 3i 2 + 4i ]
See also: real, imag, iscomplex, abs, arg.
|• Single Precision Data Types:|
|• Integer Data Types:|
|• Bit Manipulations:|
|• Logical Values:|
|• Promotion and Demotion of Data Types:|
|• Predicates for Numeric Objects:|