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44 lines
1.0 KiB
Python
44 lines
1.0 KiB
Python
import pandas as pd
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import numpy as np
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import gradio as gr
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def plot(v, a):
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g = 9.81
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theta = a / 180 * 3.14
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tmax = ((2 * v) * np.sin(theta)) / g
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timemat = tmax * np.linspace(0, 1, 40)
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x = (v * timemat) * np.cos(theta)
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y = ((v * timemat) * np.sin(theta)) - ((0.5 * g) * (timemat**2))
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df = pd.DataFrame({"x": x, "y": y})
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return df
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demo = gr.Blocks()
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with demo:
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gr.Markdown(
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r"Let's do some kinematics! Choose the speed and angle to see the trajectory. Remember that the range $R = v_0^2 \cdot \frac{\sin(2\theta)}{g}$"
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)
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with gr.Row():
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speed = gr.Slider(1, 30, 25, label="Speed")
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angle = gr.Slider(0, 90, 45, label="Angle")
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output = gr.LinePlot(
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x="x",
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y="y",
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overlay_point=True,
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tooltip=["x", "y"],
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x_lim=[0, 100],
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y_lim=[0, 60],
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width=350,
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height=300,
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)
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btn = gr.Button(value="Run")
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btn.click(plot, [speed, angle], output)
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if __name__ == "__main__":
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demo.launch()
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