New: pixel per degree calculator
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bin/ppd.py
Executable file
134
bin/ppd.py
Executable file
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#!/usr/bin/env python3
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# Pixels per degree calculator
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#
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import re
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import math
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import argparse
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from typing import *
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def diag_to_dims(diag: float, aspect_w: int, aspect_h: int) -> Tuple[float, float]:
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aspect_sq_sum = aspect_w**2 + aspect_h**2
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x = math.sqrt(diag**2 / aspect_sq_sum)
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return aspect_w * x, aspect_h * x
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def inch2cm(inch: float) -> float:
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return inch * 2.54
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def deg2rad(deg: float) -> float:
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return deg * math.pi / 180
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def rad2deg(rad: float) -> float:
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return rad * 180 / math.pi
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def ppd_min(info: dict) -> float:
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"""
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Computes the ppd exactly 1deg off from the center
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This results in a lower bound on the PPD. All distance measures are in cm
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"""
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lw, lh = diag_to_dims(info.diag, info.asc_w, info.asc_h)
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screen_dist = math.tan(deg2rad(1)) * info.eye_dist
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print(screen_dist)
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return screen_dist * info.res_w / lw
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def ppd_avg(info: dict) -> float:
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"""
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Computes the ppd using the entire width of the screen
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This results in an average of the PPD. All distance measures are in cm
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"""
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lw, lh = diag_to_dims(info.diag, info.asc_w, info.asc_h)
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angle = 2 * rad2deg(math.atan((lw/2) / info.eye_dist))
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print(f"FOV: {angle}")
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return info.res_w / angle
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def ppd_max(info: dict) -> float:
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lw, _ = diag_to_dims(info.diag, info.asc_w, info.asc_h)
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h = math.sqrt((lw/2)**2 + info.eye_dist**2)
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a = h - info.eye_dist
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o = info.eye_dist * math.tan(deg2rad(1))
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print(h)
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h_s = math.sqrt(a**2 + o**2) * (info.res_w / lw)
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return h_s
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h = math.sqrt(info.eye_dist**2 + (lw/2)**2)
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#print(h)
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#print(info.eye_dist)
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interior_adj = h - info.eye_dist
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interior_opp = info.eye_dist * math.tan(deg2rad(1))
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print(interior_adj)
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print(interior_opp)
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print(lw)
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return math.sqrt(interior_adj**2 + interior_opp**2) * info.res_w / lw
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interior_obtuse = 90.0 - rad2deg(math.atan((lw/2) / info.eye_dist))
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#interior_obtuse = 180.0 - 1.0 - interior_acute
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interior_angle = deg2rad(89.0 + rad2deg(math.atan((lw/2) / info.eye_dist)))
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interior_adj = h - info.eye_dist
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screen_length = interior_adj / math.cos(interior_angle)
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return screen_length * info.res_w
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if __name__ == "__main__":
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parser = argparse.ArgumentParser(
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prog="PPD calculator v1.0.0",
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description="Calculate the pixels per degree on a flat screen"
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);
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parser.add_argument(
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"diag", type=float,
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help="Diagonal meansure of screen in inches"
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);
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parser.add_argument(
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"res_w", type=int,
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help="Horizontal resolution of screen"
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);
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parser.add_argument(
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"res_h", type=int,
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help="Vertical resolution of screen"
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);
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parser.add_argument(
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"asc_w", type=int,
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help="Horizontal aspect ratio"
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);
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parser.add_argument(
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"asc_h", type=int,
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help="Vertical aspect ratio"
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);
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parser.add_argument(
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"eye_dist", type=int,
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help="Distance of your eyes from the screen in centimeters"
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);
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args = parser.parse_args();
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args.diag = inch2cm(args.diag)
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print(f"Pixels per degree (min): {ppd_min(args)}")
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print(f"Pixels per degree (avg): {ppd_avg(args)}")
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print(f"Pixels per degree (max): {ppd_max(args)}")
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