Translation in Computer graphics...

Please watch the following video of the translation used in freeCAD...

Translation is a fundamental transformation in computer graphics that moves an object from one position to another in a 2D or 3D space. Unlike other transformations such as scaling or rotation, translation preserves the shape and orientation of the object, altering only its position.

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Key Concepts

1. Definition: Translation involves shifting all points of an object by the same distance in a specified direction.

2. Translation Vector: A translation is defined by a vector $T = (t_x, t_y, t_z)$, where:

   • $t_x$: Translation along the x-axis.
   • $t_y$: Translation along the y-axis.
   • $t_z$: Translation along the z-axis (for 3D graphics).

3. Transformation Matrix: Translation is represented using a homogeneous coordinate matrix to allow for consistent matrix multiplication.

   • For 2D translation:

     $$T = \begin{bmatrix} 1 & 0 & t_x \\ 0 & 1 & t_y \\ 0 & 0 & 1 \end{bmatrix}$$

   • For 3D translation:

     $$T = \begin{bmatrix} 1 & 0 & 0 & t_x \\ 0 & 1 & 0 & t_y \\ 0 & 0 & 1 & t_z \\ 0 & 0 & 0 & 1 \end{bmatrix}$$

4. Point Translation: A point $P(x, y)$ (in 2D) or $P(x, y, z)$ (in 3D) is translated by multiplying its homogeneous coordinate vector with the translation matrix:

   $$P' = T \cdot P$$
   • Where $P$ is the original point, $P'$ is the translated point, and $T$ is the translation matrix.

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Example

2D Translation:

Suppose a point $P(2, 3)$ is translated by $T(4, 5)$:

$$T = \begin{bmatrix} 1 & 0 & 4 \\ 0 & 1 & 5 \\ 0 & 0 & 1 \end{bmatrix}, P = \begin{bmatrix} 2 \\ 3 \\ 1 \end{bmatrix}$$ $$P' = T \cdot P = \begin{bmatrix} 1 & 0 & 4 \\ 0 & 1 & 5 \\ 0 & 0 & 1 \end{bmatrix} \cdot \begin{bmatrix} 2 \\ 3 \\ 1 \end{bmatrix} = \begin{bmatrix} 6 \\ 8 \\ 1 \end{bmatrix}$$

The new point is $P'(6, 8)$.

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Applications

• Moving objects: Shifting the position of objects in animations, games, or simulations.
• Camera movement: Adjusting the viewpoint in a scene.
• Path planning: Moving objects along a trajectory.

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Translation in 3D Graphics

For 3D, the process is similar but includes the z-dimension. A cube or other 3D model can be moved in any direction by applying a 3D translation matrix.

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Translation is a cornerstone of computer graphics, forming the basis for more complex transformations like scaling, rotation, and perspective transformations. It plays a critical role in rendering, animation, and interactive graphics!

Here's the Python script for experimenting with translation using freeCAD.

import FreeCAD
import FreeCADGui
from PySide2 import QtWidgets

class TranslationApp(QtWidgets.QWidget):
    def __init__(self):
        super().__init__()
        self.setWindowTitle("3D Translation in FreeCAD")
        self.setGeometry(300, 300, 300, 200)
        
        # UI Components
        layout = QtWidgets.QVBoxLayout()
        
        # Create a cube button
        self.create_cube_btn = QtWidgets.QPushButton("Create Cube")
        self.create_cube_btn.clicked.connect(self.create_cube)
        layout.addWidget(self.create_cube_btn)
        
        # Translation input fields
        self.tx_input = QtWidgets.QLineEdit()
        self.tx_input.setPlaceholderText("Translation X")
        layout.addWidget(self.tx_input)
        
        self.ty_input = QtWidgets.QLineEdit()
        self.ty_input.setPlaceholderText("Translation Y")
        layout.addWidget(self.ty_input)
        
        self.tz_input = QtWidgets.QLineEdit()
        self.tz_input.setPlaceholderText("Translation Z")
        layout.addWidget(self.tz_input)
        
        # Apply translation button
        self.apply_translation_btn = QtWidgets.QPushButton("Apply Translation")
        self.apply_translation_btn.clicked.connect(self.apply_translation)
        layout.addWidget(self.apply_translation_btn)
        
        # Reset button
        self.reset_btn = QtWidgets.QPushButton("Reset Cube Position")
        self.reset_btn.clicked.connect(self.reset_position)
        layout.addWidget(self.reset_btn)
        
        self.setLayout(layout)
        self.obj = None  # Store the created object

    def create_cube(self):
        """Creates a cube in FreeCAD."""
        if not FreeCAD.ActiveDocument:
            FreeCAD.newDocument("TranslationDemo")
        else:
            FreeCAD.ActiveDocument.clearAllObjects()
        
        self.obj = FreeCAD.ActiveDocument.addObject("Part::Box", "Cube")
        self.obj.Length = 10
        self.obj.Width = 10
        self.obj.Height = 10
        FreeCAD.ActiveDocument.recompute()
        FreeCADGui.ActiveDocument.ActiveView.setAnimationEnabled(True)
        QtWidgets.QMessageBox.information(self, "Cube Created", "A cube has been created.")

    def apply_translation(self):
        """Applies translation to the cube."""
        if self.obj is None:
            QtWidgets.QMessageBox.warning(self, "Error", "Create a cube first!")
            return
        
        try:
            tx = float(self.tx_input.text())
            ty = float(self.ty_input.text())
            tz = float(self.tz_input.text())
            
            # Apply translation
            translation_vector = FreeCAD.Vector(tx, ty, tz)
            self.obj.Placement.Base += translation_vector
            
            FreeCAD.ActiveDocument.recompute()
            QtWidgets.QMessageBox.information(self, "Success", f"Translated by ({tx}, {ty}, {tz})")
        except ValueError:
            QtWidgets.QMessageBox.warning(self, "Invalid Input", "Please enter valid numbers for translation.")

    def reset_position(self):
        """Resets the cube's position to the origin."""
        if self.obj is None:
            QtWidgets.QMessageBox.warning(self, "Error", "Create a cube first!")
            return
        
        self.obj.Placement.Base = FreeCAD.Vector(0, 0, 0)
        FreeCAD.ActiveDocument.recompute()
        QtWidgets.QMessageBox.information(self, "Position Reset", "Cube position reset to origin.")

# Main function to run the UI
def show_translation_app():
    window = TranslationApp()
    window.setParent(FreeCADGui.getMainWindow(), QtCore.Qt.Window)
    window.show()

# Run the application
show_translation_app()

Career choice with the advent of AI - pure Computer Science or learn software with a background of core engineering area like mechanical, electrical, etc - which one to choose?

 The decision between pursuing a career in Computer Science and Engineering (CSE) or combining programming with a core engineering background (e.g., mechanical, electrical, civil) depends on your interests, the industry trends, and how you want to align your career with the opportunities that AI and technology advancements offer.

Here’s a detailed comparison to help you decide:

---

1. CSE Career Path (AI-Focused Software Development)

• Advantages:

  • Direct involvement with AI/ML: CSE professionals often work on cutting-edge AI technologies like deep learning, natural language processing, and computer vision.
  • Diverse opportunities: Careers in software development, data science, cybersecurity, cloud computing, and more.
  • Higher demand: With the increasing role of AI in industries, there's a massive demand for skilled software engineers who can implement AI-driven solutions.
  • Scalability of work: The software industry provides opportunities to work remotely, freelance, or start your own tech venture.

• Challenges:

  • Highly competitive: You'll need to continuously upskill in AI, data science, and new programming frameworks.
  • Abstract nature: If you're more inclined toward physical systems or hands-on work, CSE might feel disconnected from real-world applications.

• Ideal for:

  • Those who enjoy coding, problem-solving, and working in highly dynamic and tech-centric environments.
  • Individuals who want to focus exclusively on software and AI/ML technologies.

---

2. Core Engineering with Programming (Interdisciplinary Approach)

• Advantages:

  • Unique skill set: Combining programming skills with core engineering knowledge (e.g., mechanical engineering) enables you to tackle industry-specific AI applications, such as:
    • Mechanical Engineering: AI for CAD, CAM, simulations, robotics, and automation.
    • Electrical Engineering: AI in embedded systems, IoT, power systems, and renewable energy.
    • Civil Engineering: AI for smart cities, structural analysis, and resource optimization.
  • Real-world impact: You'll work on AI solutions that integrate with physical systems, bridging the gap between software and the tangible world.
  • Less saturation: There's growing demand for engineers with hybrid skills, but fewer professionals focus on this niche.

• Challenges:

  • Steeper learning curve: You'll need to gain a solid understanding of AI tools (e.g., Python, TensorFlow) while mastering domain-specific applications.
  • Limited immediate opportunities: Core engineering fields are slower to adopt AI compared to pure software development, though this is rapidly changing.
  • Dependence on specific industries: Career growth depends on how quickly your chosen field (e.g., mechanical) embraces AI.

• Ideal for:

  • Those with a passion for engineering who want to apply AI to solve real-world, domain-specific challenges.
  • Individuals who prefer working on physical systems or industry-specific projects.

---

Future Outlook

1. AI in CSE:

   • AI is fundamentally software-driven, so CSE professionals will continue to dominate the development of AI algorithms, models, and systems.
   • Growth areas: Generative AI, autonomous systems, augmented reality, and AI ethics.

2. AI in Core Engineering:

   • AI adoption in engineering fields like manufacturing, energy, and construction is accelerating.
   • Growth areas: Predictive maintenance, robotics, digital twins, and optimization algorithms.

---

Key Considerations

1. Interest and Aptitude:

   • If you enjoy coding, data, and algorithms: Go for CSE.
   • If you enjoy working with physical systems and combining programming with domain expertise: Opt for core engineering with programming.

2. Job Roles:

   • CSE: AI/ML Engineer, Data Scientist, Full-Stack Developer, Cloud Engineer.
   • Core Engineering + Programming: Robotics Engineer, Automation Specialist, AI-driven Product Developer, Simulation Engineer.

3. Market Trends:

   • While CSE offers more immediate opportunities in AI, the demand for hybrid engineers (programming + domain expertise) is rising, especially in fields like robotics, autonomous vehicles, and renewable energy.

---

Conclusion

• If you’re fascinated by technology, coding, and AI/ML, CSE offers the fastest path to AI-related careers.
• If you’re passionate about engineering and want to apply AI to tangible, real-world problems, combining core engineering with programming can give you a unique edge.

Ultimately, both paths have immense potential, but success depends on your dedication to continuously learning and adapting to technological advancements. Let me know if you'd like guidance on a specific path!

Transforming Normals in Computer Graphics...

In computer graphics, normals are vectors perpendicular to surfaces that are critical for rendering and lighting calculations. Transforming normals correctly is essential to ensure that the visual appearance of objects (such as shading, reflections, and lighting) remains accurate after transformations like scaling, rotation, or translation.

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Challenges in Normal Transformation

1. Non-Uniform Scaling:

   • Normals need special care under non-uniform scaling (e.g., scaling an object more in one direction than another) because simply applying the transformation matrix to the normal may not preserve its perpendicularity to the surface.

2. Translation:

   • Normals represent direction and not position, so translation has no effect on them and must not be applied.

3. Maintaining Unit Length:

   • Normals are typically normalized to unit length (magnitude = 1) for accurate lighting calculations. Transformations may distort their magnitude, requiring renormalization.

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Mathematics Behind Normal Transformation

Standard Transformation

For a vertex $v$, the transformation is done using the model matrix $M$:

$$v' = M \cdot v$$

However, directly applying $M$ to normals is incorrect in cases involving non-uniform scaling. This is because normals must remain perpendicular to the surface even after transformations.

Correct Normal Transformation

Normals are transformed using the inverse transpose of the model matrix $M$:

$$n' = (M^{-1})^T \cdot n$$

Here:

• $M^{-1}$: Inverse of the transformation matrix.
• $(M^{-1})^T$: Transpose of the inverse matrix.

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Why Use the Inverse Transpose?

1. Inverse:

   • Ensures that the transformed normal remains perpendicular to the surface.
   • Compensates for non-uniform scaling distortions.

2. Transpose:

   • Handles the directionality of the normal vector.

3. Avoid Translation:

   • Translation components of $M$ do not affect the normal.

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Steps to Transform a Normal

1. Extract the transformation matrix $M$ used for the object's geometry.
2. Compute the inverse transpose of $M$: $$N = (M^{-1})^T$$
3. Apply $N$ to the normal $n$ to get the transformed normal $n'$: $$n' = N \cdot n$$
4. Normalize $n'$ to ensure it is a unit vector: $$n' = \frac{n'}{||n'||}$$

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Special Cases

1. Uniform Scaling:

   • If scaling is uniform, the same factor is applied in all directions, and the normals are directly proportional to the transformation.
   • In this case, you can simply apply the transformation matrix and renormalize the result.

2. Rotation:

   • Rotations preserve angles and perpendicularity, so the normal can be directly transformed using the rotation matrix.

3. Translation:

   • Normals are not affected by translation.

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Example

Given:

• A normal vector: $n = [1, 0, 0]$
• A transformation matrix $M$:

$$M = \begin{bmatrix} 2 & 0 & 0 & 0 \\ 0 & 3 & 0 & 0 \\ 0 & 0 & 1 & 0 \\ 0 & 0 & 0 & 1 \end{bmatrix}$$

(Non-uniform scaling)

Steps:

1. Compute $M^{-1}$:

$$M^{-1} = \begin{bmatrix} \frac{1}{2} & 0 & 0 & 0 \\ 0 & \frac{1}{3} & 0 & 0 \\ 0 & 0 & 1 & 0 \\ 0 & 0 & 0 & 1 \end{bmatrix}$$

2. Compute $(M^{-1})^T$:

$$(M^{-1})^T = \begin{bmatrix} \frac{1}{2} & 0 & 0 & 0 \\ 0 & \frac{1}{3} & 0 & 0 \\ 0 & 0 & 1 & 0 \\ 0 & 0 & 0 & 1 \end{bmatrix}$$

3. Apply $(M^{-1})^T$ to $n$:

$$n' = \begin{bmatrix} \frac{1}{2} & 0 & 0 & 0 \\ 0 & \frac{1}{3} & 0 & 0 \\ 0 & 0 & 1 & 0 \\ 0 & 0 & 0 & 1 \end{bmatrix} \begin{bmatrix} 1 \\ 0 \\ 0 \\ 0 \end{bmatrix} = \begin{bmatrix} \frac{1}{2} \\ 0 \\ 0 \\ 0 \end{bmatrix}$$

4. Normalize $n'$:

$$||n'|| = \sqrt{\left(\frac{1}{2}\right)^2 + 0^2 + 0^2} = \frac{1}{2}$$ $$n' = \frac{1}{2} / \frac{1}{2} = [1, 0, 0]$$

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Applications

1. Shading and Lighting: Normals are critical for calculating how light interacts with a surface (e.g., diffuse and specular reflection).

2. Normal Mapping: Techniques like normal mapping use altered normals to simulate surface details without changing the geometry.

3. Rendering Pipelines: Correct normal transformations are necessary for accurate rendering of objects under transformations.

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Conclusion

Transforming normals in computer graphics is a key operation for ensuring visual accuracy in rendering. The use of the inverse transpose matrix for transforming normals, particularly under non-uniform scaling, ensures that they remain perpendicular to the surface and consistent with the object's geometry.

Here's the source code for experimentation of normal transformation in freeCAD...

import FreeCAD
import FreeCADGui
from PySide2 import QtWidgets, QtGui, QtCore
import Part


class NormalTransformationApp(QtWidgets.QWidget):
    def __init__(self):
        super().__init__()
        self.setWindowTitle("Normal Transformation in FreeCAD")
        self.setGeometry(200, 200, 400, 300)
        self.layout = QtWidgets.QVBoxLayout()

        # Create Buttons
        self.create_cube_btn = QtWidgets.QPushButton("Create Cube")
        self.apply_scaling_btn = QtWidgets.QPushButton("Apply Non-Uniform Scaling")
        self.reset_scaling_btn = QtWidgets.QPushButton("Reset Scaling")
        self.show_normals_btn = QtWidgets.QPushButton("Show Normals")

        # Add Buttons to Layout
        self.layout.addWidget(self.create_cube_btn)
        self.layout.addWidget(self.apply_scaling_btn)
        self.layout.addWidget(self.reset_scaling_btn)
        self.layout.addWidget(self.show_normals_btn)

        self.setLayout(self.layout)

        # Connect Buttons to Functions
        self.create_cube_btn.clicked.connect(self.create_cube)
        self.apply_scaling_btn.clicked.connect(self.apply_scaling)
        self.reset_scaling_btn.clicked.connect(self.reset_scaling)
        self.show_normals_btn.clicked.connect(self.show_normals)

    def create_cube(self):
        """Creates a cube in the FreeCAD document."""
        doc = FreeCAD.ActiveDocument
        if not doc:
            doc = FreeCAD.newDocument("NormalTransformationDemo")
        cube = doc.addObject("Part::Box", "Cube")
        cube.Length = 10
        cube.Width = 10
        cube.Height = 10
        cube.Placement = FreeCAD.Placement(FreeCAD.Vector(0, 0, 0), FreeCAD.Rotation(0, 0, 0, 1))
        doc.recompute()
        FreeCADGui.Selection.addSelection(cube)

    def apply_scaling(self):
        """Applies non-uniform scaling to the selected object."""
        selected_objects = FreeCADGui.Selection.getSelection()
        if not selected_objects:
            QtWidgets.QMessageBox.warning(self, "Warning", "No object selected.")
            return
        obj = selected_objects[0]
        scale_matrix = FreeCAD.Matrix()
        scale_matrix.A11 = 2  # Scale X by 2
        scale_matrix.A22 = 0.5  # Scale Y by 0.5
        scale_matrix.A33 = 1  # Scale Z by 1
        obj.Placement = obj.Placement.multiply(FreeCAD.Placement(scale_matrix))
        FreeCAD.ActiveDocument.recompute()

    def reset_scaling(self):
        """Resets the scaling of the selected object."""
        selected_objects = FreeCADGui.Selection.getSelection()
        if not selected_objects:
            QtWidgets.QMessageBox.warning(self, "Warning", "No object selected.")
            return
        obj = selected_objects[0]
        obj.Placement = FreeCAD.Placement(FreeCAD.Vector(0, 0, 0), FreeCAD.Rotation(0, 0, 0, 1))
        FreeCAD.ActiveDocument.recompute()

    def show_normals(self):
        """Calculates and displays normals for the faces of the selected object."""
        selected_objects = FreeCADGui.Selection.getSelection()
        if not selected_objects:
            QtWidgets.QMessageBox.warning(self, "Warning", "No object selected.")
            return
        obj = selected_objects[0]
        if not hasattr(obj, "Shape"):
            QtWidgets.QMessageBox.warning(self, "Warning", "Selected object has no shape.")
            return
        shape = obj.Shape
        normals = []
        for face in shape.Faces:
            normal = face.normalAt(0.5, 0.5)  # Normal at the center of the face
            normals.append(normal)
            # Create a visual line for the normal
            center = face.CenterOfMass
            normal_line = Part.LineSegment(center, center + normal * 5)
            normal_obj = FreeCAD.ActiveDocument.addObject("Part::Feature", "Normal")
            normal_obj.Shape = normal_line.toShape()
        FreeCAD.ActiveDocument.recompute()
        QtWidgets.QMessageBox.information(self, "Normals", f"Calculated {len(normals)} normals.")


def show_app():
    """Displays the application within FreeCAD."""
    main_window = FreeCADGui.getMainWindow()
    dock_widget = QtWidgets.QDockWidget("Normal Transformation", main_window)
    dock_widget.setWidget(NormalTransformationApp())
    main_window.addDockWidget(QtCore.Qt.RightDockWidgetArea, dock_widget)


show_app()

चरैवेति..... चरैवेति... CHARAIVETI... CHARAIVETI - my journey through the wilderness of Computer Graphics - Rotational transformation...

Source Code - python script...

import FreeCAD import FreeCADGui import Part from PySide2.QtWidgets import QApplication, QVBoxLayout, QLabel, QLineEdit, QPushButton, QWidget class RotationApp(QWidget):     def __init__(self):         super().__init__()         self.initUI()     def initUI(self):         self.setWindowTitle("Rotation in Computer Graphics")         self.setGeometry(100, 100, 300, 250)         layout = QVBoxLayout()         # Instruction label         self.label_info = QLabel("Select an object or create one for rotation:")         layout.addWidget(self.label_info)         # Button to create a default cube         self.create_button = QPushButton("Create Cube")         self.create_button.clicked.connect(self.create_cube)         layout.addWidget(self.create_button)         # Input fields for rotation angles         self.label_x = QLabel("Rotation Angle (X-axis):")         layout.addWidget(self.label_x)         self.input_x = QLineEdit("0")         layout.addWidget(self.input_x)         self.label_y = QLabel("Rotation Angle (Y-axis):")         layout.addWidget(self.label_y)         self.input_y = QLineEdit("0")         layout.addWidget(self.input_y)         self.label_z = QLabel("Rotation Angle (Z-axis):")         layout.addWidget(self.label_z)         self.input_z = QLineEdit("0")         layout.addWidget(self.input_z)         # Buttons         self.apply_button = QPushButton("Apply Rotation")         self.apply_button.clicked.connect(self.apply_rotation)         layout.addWidget(self.apply_button)         self.reset_button = QPushButton("Reset Rotation")         self.reset_button.clicked.connect(self.reset_rotation)         layout.addWidget(self.reset_button)         self.setLayout(layout)     def create_cube(self):         """Create a default cube if no object exists."""         doc = FreeCAD.ActiveDocument         if not doc:             doc = FreeCAD.newDocument("RotationDemo")         cube = Part.makeBox(10, 10, 10)         obj = doc.addObject("Part::Feature", "Cube")         obj.Shape = cube         doc.recompute()         FreeCADGui.Selection.clearSelection()         FreeCADGui.Selection.addSelection(obj)         FreeCAD.Console.PrintMessage("Cube created and selected.\n")     def get_selected_object(self):         """Get the currently selected object in FreeCAD."""         selected = FreeCADGui.Selection.getSelection()         if len(selected) == 0:             FreeCAD.Console.PrintMessage("No object selected!\n")             return None         return selected[0]     def apply_rotation(self):         """Apply rotation to the selected object."""         obj = self.get_selected_object()         if not obj:             return         try:             # Get rotation angles from input fields             angle_x = float(self.input_x.text())             angle_y = float(self.input_y.text())             angle_z = float(self.input_z.text())         except ValueError:             FreeCAD.Console.PrintMessage("Invalid input! Please enter numeric values.\n")             return         from math import radians         angle_x = radians(angle_x)         angle_y = radians(angle_y)         angle_z = radians(angle_z)         # Create rotation matrices         rotation_x = FreeCAD.Rotation(FreeCAD.Vector(1, 0, 0), angle_x)         rotation_y = FreeCAD.Rotation(FreeCAD.Vector(0, 1, 0), angle_y)         rotation_z = FreeCAD.Rotation(FreeCAD.Vector(0, 0, 1), angle_z)         # Combine rotations         combined_rotation = rotation_x.multiply(rotation_y).multiply(rotation_z)         # Update object's Placement         current_placement = obj.Placement         new_rotation = combined_rotation.multiply(current_placement.Rotation)         obj.Placement = FreeCAD.Placement(current_placement.Base, new_rotation)         FreeCAD.ActiveDocument.recompute()         FreeCAD.Console.PrintMessage(             f"Applied rotation: X={self.input_x.text()}°, Y={self.input_y.text()}°, Z={self.input_z.text()}°\n"         )     def reset_rotation(self):         """Reset the rotation of the selected object."""         obj = self.get_selected_object()         if not obj:             return         obj.Placement = FreeCAD.Placement(obj.Placement.Base, FreeCAD.Rotation())         FreeCAD.ActiveDocument.recompute()         FreeCAD.Console.PrintMessage("Rotation reset to default.\n") # Run the application if __name__ == "__main__":     if not FreeCADGui.activeWorkbench():         FreeCADGui.showMainWindow()     app = QApplication.instance()     if app is None:         app = QApplication([])     window = RotationApp()     window.show()

 Rotational transformation is a fundamental operation in computer graphics, enabling the manipulation of objects by rotating them around a fixed point or axis. This transformation is crucial in a wide array of applications, from 3D modeling and animation to virtual reality and game development. Understanding rotational transformations requires knowledge of geometric principles, trigonometric functions, and matrix algebra, which form the backbone of this operation.

---

What is Rotational Transformation?

Rotational transformation involves changing the orientation of an object while maintaining its shape and size. This operation pivots the object around a fixed point, often referred to as the center of rotation, or an axis in 3D space. The rotation can occur in two or three dimensions and is defined by:

• Angle of Rotation: Specifies the degree of rotation, typically in degrees or radians.
• Direction: Clockwise or counterclockwise in 2D, and along the X, Y, or Z-axis in 3D.

Rotational transformations preserve the object's geometric properties, such as distances and angles, making them rigid transformations.

---

Mathematical Representation

2D Rotation

In two dimensions, rotation around the origin is achieved using a rotation matrix. The new coordinates $(x', y')$ of a point after rotation by an angle $\theta$ are derived as:

$$\left[\begin{array}{c}{x}^{\mathrm{\prime }}\\ y^{\mathrm{\prime }}\end{array}\right]=\left[\begin{array}{cc}\cos \theta & -\sin \theta \\ \sin \theta & \cos \theta \end{array}\right]\left[\begin{array}{c}x\\ y\end{array}\right]$$

Where:

• $(x, y)$ are the original coordinates.
• $(x', y')$ are the transformed coordinates.
• $\theta$ is the angle of rotation.

3D Rotation

In three dimensions, rotation is more complex as it can occur around any of the principal axes. The rotation matrices for the X, Y, and Z-axes are:

• X-axis:

$$\begin{bmatrix} 1 & 0 & 0 \\ 0 & \cos \theta & -\sin \theta \\ 0 & \sin \theta & \cos \theta \end{bmatrix}$$

• Y-axis:

$$\begin{bmatrix} \cos \theta & 0 & \sin \theta \\ 0 & 1 & 0 \\ -\sin \theta & 0 & \cos \theta \end{bmatrix}$$

• Z-axis:

$$\begin{bmatrix} \cos \theta & -\sin \theta & 0 \\ \sin \theta & \cos \theta & 0 \\ 0 & 0 & 1 \end{bmatrix}$$

To achieve rotation around an arbitrary axis, more advanced techniques like quaternions or axis-angle representation are used.

Applications of Rotational Transformation

1. 3D Modeling and Animation

Rotation is essential for animating objects, creating realistic movements, and positioning objects in 3D scenes. For example, a car wheel's rotation is simulated using rotational transformation.

2. Virtual Reality and Augmented Reality

In VR and AR, objects must be rotated dynamically based on user input or device orientation to ensure an immersive experience.

3. Robotics

Rotational transformations are used in robotics to calculate the movement of joints and arms, enabling precise control of robotic mechanisms.

4. Game Development

Rotations are fundamental in game engines for camera movement, object rotations, and character animations.

5. Simulation and Visualization

In simulations, such as flight or driving simulators, rotational transformations are used to model realistic object behaviors.