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TechOverflow calculators:
You can enter values with SI suffixes like 12.2m (equivalent to 0.012) or 14k (14000) or 32u (0.000032).
The results are calculated while you type and shown directly below the calculator, so there is no need to press return or click on a Calculate button. Just make sure that all inputs are green by entering valid values.
You can enter values with SI suffixes like 12.2m (equivalent to 0.012) or 14k (14000) or 32u (0.000032).
The results are calculated while you type and shown directly below the calculator, so there is no need to press return or click on a Calculate button. Just make sure that all inputs are green by entering valid values.
lm ⚠
° ⚠
Formula
\Omega_{sr} = 2\cdot\pi\cdot(1-\cos(\frac{\theta}{2}))
I_{v} = \frac{\Phi_v}{\Omega_{sr}}
where:
- \theta is the apex angle in radians
- \Omega_{sr} is the solid angle in Steradians
- \Phi_v is the luminous flux in lux (lx).
- I_{v} is the luminous intensity in candela (cd).
Python code
You can use the UliEngineering library like this:
from UliEngineering.Physics.Light import lumen_to_candela_by_apex_angle from UliEngineering.EngineerIO import auto_format, auto_print # These are equivalent: intensity = lumen_to_candela_by_apex_angle("25 lm", "120°") # intensity = 7.9577 (cd) intensity = lumen_to_candela_by_apex_angle(25.0, 120.0) # intensity = 7.9577 (cd) # ... or get out a human-readable value: intensity_str = auto_format(lumen_to_candela_by_apex_angle, "25 lm", "120°") # "7.96 cd" # ... or print directly auto_print(lumen_to_candela_by_apex_angle, "25 lm", "120°") # prints "7.96 cd"
In case you can’t use UliEngineering, use this Python function:
import math def lumen_to_candela_by_apex_angle(flux, angle): """ Compute the luminous intensity from the luminous flux, assuming that the flux of <flux> is distributed equally around a cone with apex angle <angle>. Keyword parameters ------------------ flux : value, engineer string or NumPy array The luminous flux in Lux. angle : value, engineer string or NumPy array The apex angle of the emission cone, in degrees For many LEDs, this is >>> lumen_to_candela_by_apex_angle(25., 120.) 7.957747154594769 """ solid_angle = 2*math.pi*(1.-math.cos((angle*math.pi/180.)/2.0)) return flux / solid_angle # Usage example print(lumen_to_candela_by_apex_angle(25., 120.)) # Prints 7.957747154594769 (cd)