An underwater, multispectral light source: Difference between revisions
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'''Circuit Design''' | '''Circuit Design''' | ||
Our system needs to drive 7 high brightness LEDs. We | Our system needs to drive 7 high brightness LEDs. We selected 6 Philips LUMILEDS series LEDs to provide 6 of the 7 wavelengths we need. The wavelengths of these LEDs have been chosen such that they are evenly spread out in the optical spectrum. We also added a UV (395nm) LED that would be used primarily for measuring fluorescence in planktons/detecting fluorescent behavior in underwater organisms. The high current requirement for these LEDs(~700mA) means that we need to use a driver circuit to drive these LEDs as micro controllers cannot sink/source more than 25mA of current. Since the brightness of these LEDs should be adjustable, we need to have some form of LED dimming capability incorporated in our system. | ||
'''Optical Design''' | '''Optical Design''' | ||
Revision as of 05:33, 17 March 2015
Group members: Bhrugurajsinh Pradyumansinh Chudasama, Candice Murray, Anirban Chatterjee
Introduction
Background
Circuit Design
Our system needs to drive 7 high brightness LEDs. We selected 6 Philips LUMILEDS series LEDs to provide 6 of the 7 wavelengths we need. The wavelengths of these LEDs have been chosen such that they are evenly spread out in the optical spectrum. We also added a UV (395nm) LED that would be used primarily for measuring fluorescence in planktons/detecting fluorescent behavior in underwater organisms. The high current requirement for these LEDs(~700mA) means that we need to use a driver circuit to drive these LEDs as micro controllers cannot sink/source more than 25mA of current. Since the brightness of these LEDs should be adjustable, we need to have some form of LED dimming capability incorporated in our system.
Optical Design
Underwater light sources
Absorption of light in water
Water exhibits much higher absorption of photons than air at some wavelengths of light. This can be seen in the graph below.
Increasing the depth of the water increases the absorption, which can be modeled by the absorption equation where is the absorption coefficient for water at the wavelength of interest and and are the intensities at the final and starting locations, respectively.
Scattering in water'
Methods
LED Design
LED specifications from the manufacturer are shown in the table below. For full LED specifications, see [1].
| LED Color | Red-Orange | PC Amber | Lime | Green | Cyan | Blue |
| Lumens @ 350mA | 72 lm | 78 lm | 167 lm | 102 lm | 76 lm | 41 lm |
| Lumens @ 700mA | 134 lm | 140 lm | 313 lm | 161 lm | 122 lm | 70 lm |
| Efficacy @ 350mA | 98 Lm/W | 73 Lm/W | 174 lm/W | 100 Lm/W | 75 Lm/W | 38 Lm/W |
| Efficacy @ 700mA | 83 Lm/W | 63 Lm/W | 160 lm/W | 68 Lm/W | 51 Lm/W | 29 Lm/W |
| Typical Wavelength | 617 nm | 591 nm | 567 nm | 530 nm | 505 nm | 470 nm |
| Wavelength Range | 610 to 620 nm | 588 to 592 nm | 566 to 569 nm | 520 to 540 nm | 490 to 515 nm | 460 to 485 nm |
| Beam Angle | 125° | 120° | 125° | 125° | 125° | 125° |
| Recommended Operating Current | 700 mA | 350 mA | 700 mA | 700 mA | 700 mA | 700 mA |
| Maximum Rated Drive Current | 700 mA | 700 mA | 1000 mA | 1000 mA | 1000 mA | 1000 mA |
| Typical Forward Voltage | 2.1 Vf | 3.05 Vf | 2.75 Vf | 2.9 Vf | 2.9 Vf | 2.95 Vf |
| Maximum Forward Voltage | 2.8 Vf | 3.51 Vf | 3 Vf | 3.51 Vf | 3.51 Vf | 3.51 Vf |
| Thermal Resistance | 8 C°/W | 10.4 C°/W | 6.4 C°/W | 10.4 C°/W | 10.4 C°/W | 10.4 C°/W |
| Max Recommended Junction Temp | 135 °C | 130 °C | 150 °C | 150 °C | 150 °C | 150 °C |
| Operating Temperature Range | -40 to 120 °C | -40 to 110 °C | -40 to 135 °C | -40 to 135 °C | -40 to 135 °C | -40 to 135 °C |
| Dimensions L x W x H | 4.5 x 3 x 2 mm | 10 x 10 x 3.7 mm | 10 x 10 x 3.7 mm | 10 x 10 x 3.7 mm | 10 x 10 x 3.7 mm | 10 x 10 x 3.7 mm |
Results
Conclusions
References
1. H. Buiteveld and J. M. H. Hakvoort and M. Donze, "The optical properties of pure water," in SPIE Proceedings on Ocean Optics XII, edited by J. S. Jaffe, 2258, 174--183, (1994). [2]
2. K. S. Shifrin, Physical Optics of Ocean Water, American Institute of Physics, New York, (1988). [3]
3. "Optical Absorption of Water Compendium", [4]