|
|
|
| R2012a Documentation → MATLAB | |
Learn more about MATLAB |
|
| Contents | Index |
• Desktop Tools and Development Environment
• Graphics
• Displaying Bit-Mapped Images
• Working with Images in MATLAB Graphics
• Working with 8-Bit and 16-Bit Images
• Reading, Writing, and Querying Graphics Image Files
• The Image Object and Its Properties
Specifying Parameters and Options
Default Settings and How to Change Them
Exporting to the Windows or Macintosh Clipboard
Printing with a Specific Paper Size
Exporting in a Specific Graphics Format
Exporting in EPS Format with a TIFF Preview
Exporting a Figure to the Clipboard
Setting the Figure Size and Position
Setting the Paper Size or Type
Setting the Axes Ticks and Limits
Setting Line and Text Characteristics
Setting the Line and Text Color
Specifying a Colorspace for Printing and Exporting
Excluding User Interface Controls form Printed Output
Frequently Used Graphics Formats
Factors to Consider in Choosing a Format
Properties Affected by Choice of Format
Impact of Rendering Method on the Output
Description of Selected Graphics Formats
How to Specify a Format for Exporting
Factors to Consider in Choosing a Driver
Information on Specific Graphics Objects
Figures Used for Graphing Data
Root Object - The Figure Parent
Example - Creating Core Graphics Objects
High-Level Versus Low-Level Functions
Identifying Plot Objects Programmatically
Plot Objects and Backward Compatibility
Changing the Size of Data Variables
Example - Enclosing Subplots with an Annotation Rectangle
Order Dependence of Setting Property Values
Properties Common to All Objects
How MATLAB Searches for Default Values
Examples - Setting Default Line Styles
The Current Figure, Axes, and Object
Searching for Objects by Property Values - findobj
Specifying the Target for Graphics Output
Preparing Figures and Axes for Graphics
Targeting Graphics Output with newplot
Quitting the MATLAB Environment
Errors in the Close Request Function
Overriding the Close Request Function
Redefining the CloseRequestFcn
Example - Translating Grouped Objects
Properties for Controlling Legend Content
Example - Excluding a Particular Object From a Legend
Example - One Legend Entry for a Group of Objects
Example - Showing Children of Group Objects in Legend
Example - Grouping Objects to Reduce the Legend Entries
User Interface Object Callbacks
Why Use Function Handle Callbacks
Example - Using Function Handles in GUIs
General Performance Guidelines
Specify Axes with Plotting Function for Better Performance
Basic 3-D Plotting: The plot3 function
Functions for Plotting Data Grids
Functions for Gridding and Interpolating Data
Visualizing Functions of Two Variables
Surface Plots of Nonuniformly Sampled Data
Indexed Color Surfaces - Direct and Scaled Color Mapping
Example - Mapping Surface Curvature to Color
Move Camera Horizontally/Vertically
Move Camera Forward and Backward
Defining the Camera Path as a Stream Line
Moving In and Out on the Scene
Making the Scene Larger or Smaller
Rotation Without Resizing of Graphics Objects
Rotation About the Viewing Axis
Projection Types and Camera Location
Example - axis Command Options
Additional Commands for Setting Aspect Ratio
Default Aspect Ratio Selection
Effects of Setting Aspect Ratio Properties
Example - Displaying Cross-Sections of Surfaces
Example - Displaying Real Objects
Properties That Affect Lighting
Positioning Lights in Data Space
Example - A Transparent Isosurface
Mapping Alpha Data to the Alphamap
Example - Mapping Data to Color or Transparency
Example - Modifying the Alphamap
Behavior of the patch Function
Handling Mixed Data Specification
Coloring Edges with Shared Vertices
Interpolating in Indexed Color Versus Truecolor
Selecting Visualization Techniques
Steps to Create a Volume Visualization
Volume Visualization Functions
Example - Ways to Display MRI Data
Example - Adding Isocaps to an Isosurface
Using Scalar Techniques with Vector Data
Specifying Starting Points for Stream Plots
Accessing Subregions of Volume Data
1. Determine the Range of the Coordinates
2. Add Slice Planes for Visual Context
3. Add Contour Lines to the Slice Planes
4. Define the Starting Points for the Stream Lines
1. Select a Subset of Data to Plot
2. Calculate Curl Angular Velocity and Wind Speed
4. Define the View and Add Lighting
1. Load Data and Calculate Required Values
3. Add Contour Lines to Slice Planes
1. Specify Starting Points of the Data Range to Plot
2. Create Stream Lines to Indicate Particle Paths
4. Calculate the Stream Particle Vertices
2. Add Isocaps to the Isosurface
• Creating Graphical User Interfaces
• About the Simple GUIDE GUI Example
• Lay Out the Simple GUI in GUIDE
• Program the Simple GUIDE GUI
• Use the Completed Simple GUIDE GUI
Create the Simple Programmatic GUI Code File
• Lay Out the Simple Programmatic GUI
• Code the Simple Programmatic GUI
• Use the Completed Simple Programmatic GUI
A Working GUI with Many Components
Add Components to the GUIDE Layout Area
Define User Interface Controls
Define Panels and Button Groups
• Designing for Cross-Platform Compatibility
• Default Callback Properties in GUIDE
• Customizing Callbacks in GUIDE
• Add Code for Components in Callbacks
• Making Multiple GUIs Work Together
Example - Manipulating a Modal Dialog Box for User Input
Example - Individual GUIDE GUIs Cooperating as Icon Manipulation Tools
• GUI for Animating a 3-D View (GUIDE)
About the 3-D Animation Example
View and Run the 3-D Globe GUI
• GUI to Interactively Explore Data in a Table (GUIDE)
• List Box Directory Reader (GUIDE)
• Access Workspace Variables from a List Box (GUIDE)
• A GUI to Set Simulink Model Parameters (GUIDE)
About the Simulink Model Parameters Example
View and Run the Simulink Parameters GUI
How to Use the Simulink Parameters GUI
Program the Slider and Edit Text Components
• An Address Book Reader (GUIDE)
About the Address Book Reader Example
View and Run the Address Book Reader GUI
Run the Address Book Reader GUI
Load an Address Book Into the Reader
The Contact Phone Number Callback
Page Through Address Book - Prev/Next
• Use a Modal Dialog Box to Confirm an Operation (GUIDE)
About the Modal Dialog Example
View and Run the Modal Dialog Box GUIs
Set Up the Close Confirmation Dialog
Set Up the GUI with the Close Button
• Time Data Updates from a GUI (GUIDE)
• Create and Run a Programmatic GUI
Create Figures for Programmatic GUIs
• Add Components to a Programmatic GUI
• Compose and Code GUIs with Interactive Tools
• Set Tab Order in a Programmatic GUI
• Create Menus for a Programmatic GUI
• Create Toolbars for Programmatic GUIs
• Design Programmatic GUIs for Cross-Platform Compatibility
• Initialize a Programmatic GUI
• Examples: Program GUI Components
• Share Data Among a GUI's Callbacks
• GUI with Axes, Menu, and Toolbar
About the Axes, Menu, and Toolbar Example
View and Run the AxesMenuToolbar Code
Generate the Graphing Commands and Data
• GUI that Displays and Graphs Tabular Data
View and Run the tableplot Code
Set Up and Interact with the uitable
Handle Graphics Property Browser
Why Write Custom Applications?
Exchanging Data Files Between Platforms
Overview of matimport.c Example
Declare Variables for External Data
Read External Data into mxArray Data
Creating a MAT-File in Fortran
Examples for Working with mxArrays
Building on Windows Operating Systems
Deploying MAT-File Applications
Limitations to Shared Library Support
Troubleshooting Shared Library Applications
Examples of Passing Data to Shared Libraries
Manually Converting Data Passed to Functions
Constructing a libpointer Object
Creating a Pointer to a Primitive Type
Creating a Pointer to a Structure
Passing a Pointer to the First Element of an Array
Putting a String into a Void Pointer
Memory Allocation for an External Library
Working with Structures Examples
Example of Passing a MATLAB Structure
Using the Structure as an Object
Introduction to Source MEX-Files
Overview of Creating a Binary MEX-File
Using Help Files with MEX-Files
Workspace for MEX-File Functions
Selecting a Compiler on Windows Platforms
Selecting a Compiler on UNIX Platforms
Overview of Building the timestwo MEX-File
Understanding MEX-File Problems
Compiler and Platform-Specific Issues
Custom Building on UNIX Systems
Custom Building on Windows Systems
Creating a MEX-File Using LAPACK and BLAS Functions
Preserving Input Values from Modification
Passing Arguments to Fortran Functions from C/C++ Programs
Passing Arguments to Fortran Functions from Fortran Programs
Handling Complex Numbers in LAPACK and BLAS Functions
Modifying the Function Name on UNIX Systems
MEX Uses 32-Bit API by Default
How to Upgrade MEX-Files to Use the 64-Bit API
Passing Two or More Inputs or Outputs
Passing Structures and Cell Arrays
Handling 8-, 16-, and 32-Bit Data
Manipulating Multidimensional Numerical Arrays
Calling Functions from C/C++ MEX-Files
Using C++ Features in MEX-Files
Debugging on the Microsoft Windows Platforms
Building Cross-Platform Applications
Specifying Constant Literal Values
Replacing fseek and ftell with 64-Bit Functions
Determining the Size of an Open File
Determining the Size of a Closed File
Using the Fortran %val Construct
Passing Two or More Inputs or Outputs
Calling Functions from Fortran MEX-Files
Debugging on Microsoft Windows Platforms
Building Cross-Platform Applications
What You Need to Build Engine Applications
Calling MATLAB Software from a C Application
Calling MATLAB Software from a C++ Application
Calling MATLAB Software from a Fortran Application
Attaching to an Existing MATLAB Session
Building and Running Engine Applications on Windows Operating Systems
Windows Engine Example engwindemo
Building and Running Engine Applications on UNIX Operating Systems
Files Required by Engine Applications
Debugging MATLAB Functions Used in Engine Applications
Benefits of the MATLAB Java Interface
Who Should Use the MATLAB Java Interface
To Learn More About Java Programming Language
Platform Support for JVM Software
Making Java Classes Available in MATLAB Workspace
Loading Java Class Definitions
Locating Native Method Libraries
Java Classes Contained in a JAR File
Saving and Loading Java Objects to MAT-Files
Finding the Public Data Fields of an Object
Accessing Private and Public Data
Determining the Class of an Object
Invoking Static Methods on Java Classes
Obtaining Information About Methods
Java Methods That Affect MATLAB Commands
How MATLAB Software Handles Undefined Methods
How MATLAB Software Handles Java Exceptions
Method Execution in MATLAB Software
How MATLAB Software Represents the Java Array
Creating an Array of Objects in MATLAB Software
Accessing Elements of a Java Array
Creating a New Array Reference
Creating a Copy of a Java Array
Conversion of MATLAB Argument Data
Passing Data to Overloaded Methods
Conversion of Java Return Types
Converting Objects to MATLAB Types
Description of Function phonebook
Description of Function pb_lookup
Description of Function pb_add
Description of Function pb_remove
Description of Function pb_change
Description of Function pb_listall
Description of Function pb_display
Description of Function pb_keyfilter
Benefits of the MATLAB .NET Interface
Why Use the MATLAB .NET Interface?
What's the Difference Between the MATLAB .NET Interface and MATLAB Builder NE?
Using a .NET assembly in MATLAB
To Learn More About the .NET Framework
Loading .NET Assemblies into MATLAB
Building a .NET Application for MATLAB Examples
What Classes Are in a .NET Assembly?
Using the delete Function on a .NET Object
How MATLAB Maps C# Property and Field Access Modifiers
Calling .NET Methods with Optional Arguments
Calling .NET Extension Methods
Call .NET Properties That Take an Argument
How MATLAB Represents .NET Operators
Limitations to Support of .NET Methods
Limitations to Support of .NET Events
Handling Data Returned from a .NET Object
Accessing .NET Array Elements in MATLAB
Converting .NET Arrays to Cell Arrays
Limitations to Support of .NET Arrays
Call a .NET Delegate in MATLAB
Create a Delegate from a .NET Object Method
Create a Delegate Instance Bound to a .NET Method
Use .NET Delegates With the out and ref Type Arguments
Combine and Remove .NET Delegates
Calling a .NET Method Asynchronously
Limitations to Support of .NET Delegates
Iterate Through a .NET Enumeration
Use .NET Enumerations to Test for Conditions
Example - Read Special System Folder Path
Use Bit Flags with .NET Enumerations
Limitations to Support of .NET Enumerations
Work with Microsoft Word Documents Using .NET
Accessing Items in a .NET Collection
Convert a .NET Collection to a MATLAB Array
Create .NET Array of Generic Type
Display .NET Generic Methods Using Reflection
Create .NET Object From Constructor
View Information About .NET Object
Introduction to .NET Data Types
Use .NET Numeric Types in MATLAB
Do Not Use ClassName.PropertyName Syntax for Static Properties
Call .NET Methods That Use the out Keyword
Call .NET Methods That Use the ref Keyword
Call .NET Methods That Use the params Keyword
Create a Cell Array for Each System.Object
Create MATLAB Variables from the .NET Data
Call MATLAB Functions with MATLAB Variables
The MATLAB COM Automation Server
Registering Controls and Servers
Overview of MATLAB COM Client Examples
Example - Using Internet Explorer Program in a MATLAB Figure
Example - Grid ActiveX Control in a Figure
Example - Reading Excel Spreadsheet Data
MATLAB Client and In-Process Server
MATLAB Client and Out-of-Process Server
COM Implementations Supported by MATLAB Software
Client Application and MATLAB Automation Server
Client Application and MATLAB Engine Server
Identifying Objects and Interfaces
Setting the Value of a Property
Using Enumerated Values for Properties
Properties That Take Arguments
Exceptions to Using Implicit Syntax
Specifying Enumerated Parameters
Returning Multiple Output Arguments
Argument Callouts in Error Messages
Functions for Working with Events
Responding to Events - an Overview
Responding to Events - Examples
Writing Event Handlers as MATLAB File Subfunctions
Releasing COM Interfaces and Objects
Handling Data from a COM Object
Passing MATLAB Data to ActiveX Objects
Passing MATLAB SAFEARRAY to COM Object
Reading SAFEARRAY from a COM Object in MATLAB Applications
Displaying MATLAB Syntax for COM Objects
Using a MATLAB Application as an Automation Client
Connecting to an Existing Excel Application
Running a Macro in an Excel Server Application
Using Microsoft Forms 2.0 Controls
Using MATLAB Application as a DCOM Client
MATLAB COM Support Limitations
Connecting to an Existing MATLAB Server
Executing Commands in the MATLAB Server
Exchanging Data with the Server
Terminating the Server Process
Specifying a Shared or Dedicated Server
Using MATLAB Application as a DCOM Server
Example - Viewing Methods from a Visual Basic .NET Client
Example - Calling MATLAB Software from a Web Application
Example - Calling MATLAB Software from a C# Client
What You Need to Use Web Services with MATLAB
Typical Applications Using Web Services with MATLAB
How MATLAB Accesses Web Services
Example - createClassFromWsdl Function
Tools for Creating Web Services
Supported Serial Port Interface Standards
Using the Examples with Your Device
The Serial Port Interface Standard
Connecting Two Devices with a Serial Cable
Serial Port Signals and Pin Assignments
Finding Serial Port Information for Your Platform
Using Virtual USB Serial Ports
Configuring and Returning Properties
Configuring Properties During Object Creation
The Serial Port Object Display
Creating an Array of Serial Port Objects
Example - Introduction to Writing and Reading Data
Controlling Access to the MATLAB Command Line
Example - Writing and Reading Text Data
Example - Parsing Input Data Using textscan
Example - Introduction to Events and Callbacks
Event Types and Callback Properties
Responding To Event Information
Creating and Executing Callback Functions
Enabling Callback Functions After They Error
Example - Using Events and Callbacks
Signaling the Presence of Connected Devices
Controlling the Flow of Data: Handshaking
Example: Introduction to Recording Information
Creating Multiple Record Files
Example: Recording Information to Disk
Using Serial Port Objects on Different Platforms
• Examples
| On this page… |
|---|
In its native form, a graphics file format image is not stored as a MATLAB matrix, or even necessarily as a matrix. Most graphics files begin with a header containing format-specific information tags, and continue with bitmap data that can be read as a continuous stream. For this reason, you cannot use the standard MATLAB I/O commands load and save to read and write a graphics file format image.
Call special MATLAB functions to read and write image data from graphics file formats:
To read a graphics file format image use imread.
To write a graphics file format image, use imwrite.
To obtain information about the nature of a graphics file format image, use imfinfo.
This table gives a clearer picture of which MATLAB commands should be used with which image types.
Procedure | Functions to Use |
|---|---|
Load or save a matrix as a MAT-file. | |
Load or save graphics file format image, e.g., BMP, TIFF. | |
Display any image loaded into the MATLAB workspace. | |
Utilities |
The imread function reads an image from any supported graphics image file in any of the supported bit depths. Most of the images that you read are 8-bit. When these are read into memory, they are stored as class uint8. The main exception to this rule is MATLAB support for 16-bit data for PNG and TIFF images; if you read a 16-bit PNG or TIFF image, it is stored as class uint16.
Note For indexed images, imread always reads the colormap into an array of class double, even though the image array itself can be of class uint8 or uint16. |
The following commands read the image ngc6543a.jpg into the workspace variable RGB and then displays the image using the image function:
RGB = imread('ngc6543a.jpg');
image(RGB)
You can write (save) image data using the imwrite function. The statements
load clown % An image that is included with MATLAB
imwrite(X,map,'clown.bmp')
create a BMP file containing the clown image.
When you save an image using imwrite, the default behavior is to automatically reduce the bit depth to uint8. Many of the images used in MATLAB are 8-bit, and most graphics file format images do not require double-precision data. One exception to the rule for saving the image data as uint8 is that PNG and TIFF images can be saved as uint16. Because these two formats support 16-bit data, you can override the MATLAB default behavior by specifying uint16 as the data type for imwrite. The following example shows writing a 16-bit PNG file using imwrite.
imwrite(I,'clown.png','BitDepth',16);
Sometimes you want to work with only a portion of an image file or you want to break it up into subsections. Specify the intrinsic coordinates of the rectangular subsection you want to work with and save it to a file from the command line. If you do not know the coordinates of the corner points of the subsection, choose them interactively, as the following example shows:
% Read demo RGB image from graphics file.
im = imread('street2.jpg');
% Display image with true aspect ratio
image(im); axis image
% Use ginput to select corner points of a rectangular
% region by pointing and clicking the mouse twice
p = ginput(2);
% Get the x and y corner coordinates as integers
sp(1) = min(floor(p(1)), floor(p(2))); %xmin
sp(2) = min(floor(p(3)), floor(p(4))); %ymin
sp(3) = max(ceil(p(1)), ceil(p(2))); %xmax
sp(4) = max(ceil(p(3)), ceil(p(4))); %ymax
% Index into the original image to create the new image
MM = im(sp(2):sp(4), sp(1): sp(3),:);
% Display the subsetted image with appropriate axis ratio
figure; image(MM); axis image
% Write image to graphics file.
imwrite(MM,'street2_cropped.tif') If you know what the image corner coordinates should be, you can manually define sp in the preceding example rather than using ginput.
You can also display a "rubber band box" as you interact with the image to subset it. See the code example for rbbox for details. For further information, see the documentation for the ginput and image functions.
The imfinfo function enables you to obtain information about graphics files in any of the standard formats listed earlier. The information you obtain depends on the type of file, but it always includes at least the following:
Name of the file, including the folder path if the file is not in the current folder
File format
Version number of the file format
File modification date
File size in bytes
Image width in pixels
Image height in pixels
Number of bits per pixel
Image type: RGB (truecolor), intensity (grayscale), or indexed
 | Working with 8-Bit and 16-Bit Images | Displaying Graphics Images |  |
Includes the most popular MATLAB recorded presentations with Q&A sessions led by MATLAB experts.
| © 1984-2012- The MathWorks, Inc. - Site Help - Patents - Trademarks - Privacy Policy - Preventing Piracy - RSS |
