====== Mechanism design ======

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====== Week2 ======

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{{ :airspace:mechanism_design:finding_the_grashof_condition_using_matlab_2_.pdf |}}

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{{ :airspace:mechanism_design:module_1-part_1_kinematics_fundamentals_terminology._dof_v1_4_.pdf |}}

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{{ :airspace:mechanism_design:module_1-part_2_kinematics_fundamentals_inversion_9_.pdf |}}

{{pdfjs 46em >:airspace:mechanism_design:module_1-part_2_kinematics_fundamentals_inversion_9_.pdf}}

{{ :airspace:mechanism_design:module_1-part_3_grashof_condition_9_.pdf |}}

{{pdfjs 46em >:airspace:mechanism_design:module_1-part_3_grashof_condition_9_.pdf}}

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====== Week3 ======
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{{ :airspace:mechanism_design:linkage_mechanism_designer_and_simulator_tutorial_1.mp4 |}}


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{{ :airspace:mechanism_design:linkage_tutorial_2_sliding_connections.mp4 |}}
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{{ :airspace:mechanism_design:module_2_part_1._graphical_linkage_synthesis_dimensional_synthesis._function_generation_2_.pdf |}}


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{{ :airspace:mechanism_design:module_2_part_2._graphical_linkage_synthesis_motion_generation_2_.pdf |}}

{{pdfjs 46em >:airspace:mechanism_design:module_2_part_2._graphical_linkage_synthesis_motion_generation_2_.pdf}}

{{ :airspace:mechanism_design:module_2_part_3._graphical_linkage_synthesis_quick_returns_6_.pdf |}}


{{pdfjs 46em >:airspace:mechanism_design:module_2_part_3._graphical_linkage_synthesis_quick_returns_6_.pdf }}

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====== Week4 ======
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{{ :airspace:mechanism_design:kinematics_design_position_analysis_using_newton_raphson_n-r_method_v2.pdf |}}

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{{ :airspace:mechanism_design:module_3-position_analysis_of_linkages_graphical_analytical_v2_2_.pdf |}}

{{pdfjs 46em >:airspace:mechanism_design:module_3-position_analysis_of_linkages_graphical_analytical_v2_2_.pdf }}

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====== Week5 ======

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{{ :airspace:mechanism_design:velocity_analysis_of_a_fourbar_mechanism_using_ptc_creo_3_.pdf |}}


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{{ :airspace:mechanism_design:module_4_part_1._velocity_analysis_of_linkages_graphical_method_3_.pdf |}}

{{pdfjs 46em >:airspace:mechanism_design:module_4_part_1._velocity_analysis_of_linkages_graphical_method_3_.pdf  }}


{{ :airspace:mechanism_design:module_4_part_2._velocity_analysis_of_linkages_velocity_polygon._an_example_3_.pdf |}}

{{pdfjs 46em >:airspace:mechanism_design:module_4_part_2._velocity_analysis_of_linkages_velocity_polygon._an_example_3_.pdf  }}


{{ :airspace:mechanism_design:module_4_part_3._velocity_analysis_of_linkages_analytical_method_3_.pdf |}}



{{pdfjs 46em >:airspace:mechanism_design:module_4_part_3._velocity_analysis_of_linkages_analytical_method_3_.pdf  }}



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{{ :airspace:mechanism_design:four_bar_synthesis_for_3_known_coupler_positions_2_.mp4 |}}


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{{ :airspace:mechanism_design:creo_parametric_-_dimensions_in_sketch_mode.mp4 |}}


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{{ :airspace:mechanism_design:creo_parametric_-_measure_tool_tutorial_1_.mp4 |}}


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**{{ :airspace:mechanism_design:22514239.pdf |Acceleration Polygon}}**

{{pdfjs 46em >:airspace:mechanism_design:22514239.pdf  }}

**{{ :airspace:mechanism_design:22510294.pdf |Acceleration analysis of linkages}}**

{{pdfjs 46em >:airspace:mechanism_design:22510294.pdf  }}

{{ :airspace:mechanism_design:acceleration_exc01.pdf |Acceleration_exc01 V1.}}

{{pdfjs 46em >:airspace:mechanism_design:acceleration_exc01.pdf  }}

{{ :airspace:mechanism_design:acceleration_exc01_1_.pdf |Acceleration_exc01 V2.}}

{{pdfjs 46em >:airspace:mechanism_design:acceleration_exc01_1_.pdf  }}

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{{ :airspace:mechanism_design:13844444.pdf |Cam-Follower Kinematics}}

{{pdfjs 46em >:airspace:mechanism_design:13844444.pdf  }}

^ Método                          ^ Tipo de Función            ^ Continuidad de Jerk ^ Suavidad del Movimiento ^ Complejidad  ^ Uso Industrial                 ^ Ventajas Clave                                              ^ Aplicaciones Típicas                                           ^
| 🔶 **Cicloidal (Cycloidal)**    | Trigonométrica (seno)      | ✔️ Muy buena         | ✔️ Alta                  | Media        | ✔️ Muy común en precisión       | Mínima aceleración al inicio y final del trazo               | Relojes, robots, pick-and-place, microactuadores              |
| 🔷 **Polinomio Quíntico**       | Polinómica grado 5         | ✔️ Excelente         | ✔️ Muy alta              | Alta         | ✔️ Alta en industria avanzada   | Suave, flexible, control sobre condiciones en extremos        | CNC, automotriz, control numérico, CAD/CAM                   |
| Armónica (Harmonic)            | Trigonométrica (coseno)    | ✖ Discontinuo        | ✔️ Alta                  | Baja         | ✔️ Común en alta velocidad      | Movimiento suave y simétrico                                 | Máquinas herramienta, motores paso a paso                    |
| Aceleración Constante          | Polinómica (grado 2)       | ✖ Discontinua        | ⚠️ Media                 | Muy baja     | ✔️ En sistemas de bajo costo    | Fácil de calcular y fabricar                                 | Prensas mecánicas, sistemas neumáticos simples               |
| Velocidad Constante            | Lineal                     | ❌ Muy mala           | ❌ Baja                  | Muy baja     | ❌ Rara vez usada               | Simple, pero causa choques fuertes                           | Sistemas muy lentos, automatización antigua                  |
| Polinomio Séptico              | Polinómica grado 7         | ✔️ Excelente         | ✔️ Máxima                | Muy alta     | ⚠️ Usado en investigación        | Control adicional sobre jerk y sobreajustes                  | Investigación avanzada, diseño experimental de levas         |



^ Method                          ^ Function Type              ^ Jerk Continuity     ^ Motion Smoothness        ^ Complexity   ^ Industrial Use                 ^ Key Advantages                                              ^ Typical Applications                                           ^
| 🔶 **Cycloidal**                | Trigonometric (sine)       | ✔️ Very good         | ✔️ High                   | Medium       | ✔️ Widely used in precision     | Minimal acceleration at the start and end of the stroke      | Watches, robots, pick-and-place, microactuators              |
| 🔷 **Quintic Polynomial**       | 5th-degree polynomial       | ✔️ Excellent         | ✔️ Very high              | High         | ✔️ Used in advanced industry    | Smooth, flexible, control over boundary conditions           | CNC, automotive, numerical control, CAD/CAM                  |
| Harmonic                       | Trigonometric (cosine)     | ✖ Discontinuous      | ✔️ High                   | Low          | ✔️ Common in high-speed systems | Smooth and symmetric motion                                  | Machine tools, stepper motors                                |
| Constant Acceleration          | Polynomial (2nd degree)    | ✖ Discontinuous      | ⚠️ Medium                 | Very low     | ✔️ In low-cost systems          | Easy to calculate and manufacture                            | Mechanical presses, simple pneumatic systems                 |
| Constant Velocity              | Linear                     | ❌ Very poor          | ❌ Low                    | Very low     | ❌ Rarely used                  | Simple, but causes strong impacts                            | Very slow systems, old automation                            |
| Septic Polynomial              | 7th-degree polynomial       | ✔️ Excellent         | ✔️ Maximum                | Very high    | ⚠️ Used in research             | Additional control over jerk and overshoot                   | Advanced research, experimental cam profile design           |



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{{ :airspace:mechanism_design:13973658.pdf |Cam-Follower Systems – Part #1}}


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{{ :airspace:mechanism_design:13844446.pdf |Cam-Follower Systems – Part #2}}

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{{ :airspace:mechanism_design:14145654.pdf |Drawing the CamProfile – Part #3}}

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{{ :airspace:mechanism_design:14145655.pdf |Cam-Follower Systems – Part #4}}


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{{ :airspace:mechanism_design:15959331.pdf |Gears and Gear Trains – Part #1}}

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{{ :airspace:mechanism_design:17935927.pdf |Planetary Gear Trains – Part #2}}

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{{ :airspace:mechanism_design:6463399.pdf |Practice Problems}}

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**{{ :airspace:mechanism_design:svaj_coefficients.pdf |Design of a CAM Profile Using Quintic Polynomial (SVAJ)}}**

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**{{ :airspace:mechanism_design:intro.pdf |Cycloidal Motion of a Cam-Follower System}}**

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{{ :airspace:mechanism_design:hw4_final_antonio_perez.pdf |}}

{{pdfjs 46em >:airspace:mechanism_design:hw4_final_antonio_perez.pdf}}

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{{ :airspace:mechanism_design:hw5_antonio_perez.pdf |}}


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