According to the given question, we have to explain how a Differential Equation Becomes a Robot arm using MuPad. • In step 2, first we explain how Differential Equation Becomes a Robot arm and after that we will provide full explanation to achieve this process. • Let's start with Step 2. How Differential Equations become Robots : Creating equations of motion using the MuPAD interface in Symbolic Math Toolbox Modeling complex electromechanical systems using Simulink and the physical modeling libraries. Importing three-dimensional mechanisms directly from CAD packages using the SimMechanics translator. Robotics have Math: Mathematics There are not many "core" skills in robotics (i.e. topics that can't be learned as you go along). One of these core skills is Mathematics. You would probably find it challenging to succeed in robotics without a good grasp of at least algebra, calculus, and geometry. How do you make a robot formula: Torque *rps >= Mass * Acceleration * Velocity/(2*pi) 1.To use this equation, look up a set of motors you think will work for your robot and write down the torque and rps (rotations per second) for each. 2.Then multiply the two numbers together for each. 3.Next, estimate the weight of your robot. DOF of a robot: Let us recall first that the mobility, or number of DOF, of a robot is defined as the number of independent joint variables required to specify the location of all the links of the robot in space. It is equal to the minimal number of actuated joints to control the system. How linear algebra is used in robotics: Linear algebra is fundamental to robot modeling, control, and optimization. This perspective illuminates the underlying structure and behavior of linear maps and simplifies analysis, especially for reduced rank matrices. How can make a simple robot: Step 1: Get the Tools and Materials You Need Together. Step 2: Assemble the Chassis. Step 3: Build and Mount the Whiskers. Step 4: Mount the Breadboard. Step 5: Modify and Mount the Battery Holder. Step 6: Mount the Power Switch If You Are Using One. Step 7: Wire It Up. Step 8: Power It on and Fix Any Issues. Run a calculator on a robot: Name your program GO. PROGRAM: GO: Send ({222}): Get (R): Disp R: Stop These commands instruct the robot to move forward until its bumper runs into something. Attach your graphing calculator to the robot and run GO. Calculate the speed of a robot : Divide the distance traveled by the average time to obtain the speed of your robot (d/t=r). For example, 100 cm/5.67 sec = a speed or rate of approximately 17.64 cm/sec. Your robot travels 17.64 cm every second.