双极性晶体管

二极管

ESD保护、TVS、滤波和信号调节ESD保护

MOSFET

氮化镓场效应晶体管(GaN FET)

绝缘栅双极晶体管(IGBTs)

模拟和逻辑IC

汽车应用认证产品(AEC-Q100/Q101)

Light Energy Harvesting - Energy Balance Calculator

Everything is a matter of energy balance between what is consumed and what is harvested. Use our simple tool below to preview what your energy compensation will be in an energy harvesting system using our solutions.

With this calculator the amount of harvested light energy can be calculated based on light intensity, cell size and chip efficiency. Select one of the pre-loaded cases to automatically fill in the values if you don't have precise working values yet. If you have a precise use case, click on custom and start typing your custom values in the next columns.

Preloaded cases

Need some inspiration to get started?
Select one pre-loaded cases to fill in the values.

Environment

Select the desired Nexperia Energy Harvesting IC product.

Illuminance

lluminance Info

Av. Illuminance (Lux)

Here are some tips to select the light intensity.

For indoor evironments, based on the European Standard prEN 12464-1:

20 - 50 Walls, Ceilings
100 - 150 Stairways, escalators - storage spaces
150 - 300 Warehouses, waiting rooms, theaters, archives, Coffee break room
300 - 500 General lighting, Class rooms, Arrival and departure halls
500 - 700 Normal office work, study library, groceries and Supermarkets, show rooms, laboratories, kitchens, auditoriums
750 - 1000 Normal drawing work, Demonstration table, Examination and treatment rooms
1500 - 2000 Very detailed mechanical works, electronic workshops, testing and adjustments
2000 - 5000 Performance of visual tasks of low contrast and very small size for prolonged periods of time

For outdoor environments:

400 Sunrise or Sunset on a clear day
1000 Overcast Day
10,000 - 25,000 Full daylight (not direct sun)
100,000 Direct sunlight

 

Time of Exposition

How many hours, per day, the application will be exposed to the light.

PV Module

Power Density

Power density consists of the maximum amount of power that can be generated by unity of area in a PV module. It is dictated by the technology employed in the PV module. The higher the power density, the better, because the PV will generate more energy in a smaller space. But the lower the power density, the lower will be the cost of a module. Here are some power densities - Just as a reference.
 
The power density can be obtained by dividing the maximum deliverable power of a PV (under 200lux) by the entire PV area.
 
The power density of indoor PVs, in uW/cm², specified at 200 lux: 2 to 10 uW/cm²
The power density of outdoor PVs, in uW/cm², specified at 200 lux: up to 40 uW/cm²
 
Always enter this value in uW/cm², specified at 200Lux.

 

Available Area

What is the maximum available product to place the PV, in cm²?

Load

Daily Energy Consumption

There are multiple ways to define the daily energy consumption:

  1. You may have the power profile of your device So you have a clear picture of the power consumption under common scenarios
     
  2. Battery information and autonomy Considering a battery fully charged, how long the product will run before the battery runs empty? with this information, you just need to divide the battery energy and the autonomy, in days, to get the daily energy consumption.

Support

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