minus, -
Subtraction
Syntax
Description
C =
subtracts array A
- B
B
from array A
by
subtracting corresponding elements. The sizes of A
and
B
must be the same or be compatible.
If the sizes of A
and B
are compatible,
then the two arrays implicitly expand to match each other. For example, if
A
or B
is a scalar, then the scalar is
combined with each element of the other array. Also, vectors with different
orientations (one row vector and one column vector) implicitly expand to form a
matrix.
Examples
Subtract Scalar from Array
Create an array, A
, and subtract a scalar value from it.
A = [2 1; 3 5]; C = A - 2
C = 2×2
0 -1
1 3
The scalar is subtracted from each entry of A
.
Subtract Two Arrays
Create two arrays, A
and B
, and subtract the second, B
, from the first, A
.
A = [1 0; 2 4]; B = [5 9; 2 1]; C = A - B
C = 2×2
-4 -9
0 3
The elements of B
are subtracted from the corresponding elements of A
.
Use the syntax -C
to negate the elements of C
.
-C
ans = 2×2
4 9
0 -3
Subtract Row and Column Vectors
Create a 1-by-2 row vector and 3-by-1 column vector and subtract them.
a = 1:2; b = (1:3)'; a - b
ans = 3×2
0 1
-1 0
-2 -1
The result is a 3-by-2 matrix, where each (i,j) element in the matrix is equal to a(j) - b(i)
:
Subtract Mean from Matrix
Create a matrix, A
. Scale the elements in each column by subtracting the mean.
A = [1 9 3; 2 7 8]
A = 2×3
1 9 3
2 7 8
A - mean(A)
ans = 2×3
-0.5000 1.0000 -2.5000
0.5000 -1.0000 2.5000
Subtract Tables
Since R2023a
Create two tables and subtract one of them from the other. The row names (if present in both) and variable names must be the same, but do not need to be in the same orders. Rows and variables of the output are in the same orders as the first input.
A = table([1;2],[3;4],VariableNames=["V1","V2"],RowNames=["R1","R2"])
A=2×2 table
V1 V2
__ __
R1 1 3
R2 2 4
B = table([4;2],[3;1],VariableNames=["V2","V1"],RowNames=["R2","R1"])
B=2×2 table
V2 V1
__ __
R2 4 3
R1 2 1
C = A - B
C=2×2 table
V1 V2
__ __
R1 0 1
R2 -1 0
Input Arguments
A
, B
— Operands
scalars | vectors | matrices | multidimensional arrays | tables | timetables
Operands, specified as scalars, vectors, matrices, multidimensional
arrays, tables, or timetables. Inputs A
and
B
must either be the same size or have sizes that are
compatible (for example, A
is an
M
-by-N
matrix and
B
is a scalar or
1
-by-N
row vector). For more
information, see Compatible Array Sizes for Basic Operations.
Operands with an integer data type cannot be complex.
If one input is a
datetime
array,duration
array, orcalendarDuration
array, then numeric values in the other input are treated as a number of 24-hour days.
Inputs that are tables or timetables must meet the following conditions: (since R2023a)
If an input is a table or timetable, then all its variables must have data types that support the operation.
If only one input is a table or timetable, then the other input must be a numeric or logical array.
If both inputs are tables or timetables, then:
Both inputs must have the same size, or one of them must be a one-row table.
Both inputs must have variables with the same names. However, the variables in each input can be in a different order.
If both inputs are tables and they both have row names, then their row names must be the same. However, the row names in each input can be in a different order.
If both inputs are timetables, then their row times must be the same. However, the row times in each input can be in a different order.
Data Types: single
| double
| int8
| int16
| int32
| int64
| uint8
| uint16
| uint32
| uint64
| logical
| char
| datetime
| duration
| calendarDuration
| table
| timetable
Complex Number Support: Yes
Extended Capabilities
Tall Arrays
Calculate with arrays that have more rows than fit in memory.
The
minus
function fully supports tall arrays. For more information,
see Tall Arrays.
C/C++ Code Generation
Generate C and C++ code using MATLAB® Coder™.
Usage notes and limitations:
If you use
minus
with single type and double type operands, the generated code might not produce the same result as MATLAB®. See Binary Element-Wise Operations with Single and Double Operands (MATLAB Coder).
GPU Code Generation
Generate CUDA® code for NVIDIA® GPUs using GPU Coder™.
Usage notes and limitations:
If you use
minus
with single type and double type operands, the generated code might not produce the same result as MATLAB. See Binary Element-Wise Operations with Single and Double Operands (MATLAB Coder).
Thread-Based Environment
Run code in the background using MATLAB® backgroundPool
or accelerate code with Parallel Computing Toolbox™ ThreadPool
.
This function fully supports thread-based environments. For more information, see Run MATLAB Functions in Thread-Based Environment.
GPU Arrays
Accelerate code by running on a graphics processing unit (GPU) using Parallel Computing Toolbox™.
The minus
function
fully supports GPU arrays. To run the function on a GPU, specify the input data as a gpuArray
(Parallel Computing Toolbox). For more information, see Run MATLAB Functions on a GPU (Parallel Computing Toolbox).
Distributed Arrays
Partition large arrays across the combined memory of your cluster using Parallel Computing Toolbox™.
This function fully supports distributed arrays. For more information, see Run MATLAB Functions with Distributed Arrays (Parallel Computing Toolbox).
Version History
Introduced before R2006aR2023a: Perform operations directly on tables and timetables
The minus
operator supports operations directly on tables and
timetables without indexing to access their variables. All variables must have data types
that support the operation. For more information, see Direct Calculations on Tables and Timetables.
R2020b: Implicit expansion change affects calendarDuration
, datetime
, and duration
arrays
Starting in R2020b, minus
supports implicit expansion when the
arguments are calendarDuration
, datetime
, or
duration
arrays. Between R2020a and R2016b, implicit
expansion was supported only for numeric data types.
R2016b: Implicit expansion change affects arguments for operators
Starting in R2016b with the addition of implicit expansion, some combinations of arguments for basic operations that previously returned errors now produce results. For example, you previously could not add a row and a column vector, but those operands are now valid for addition. In other words, an expression like [1 2] + [1; 2]
previously returned a size mismatch error, but now it executes.
If your code uses element-wise operators and relies on the errors that MATLAB previously returned for mismatched sizes, particularly within a try
/catch
block, then your code might no longer catch those errors.
For more information on the required input sizes for basic array operations, see Compatible Array Sizes for Basic Operations.
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