Light Emitting Diodes

LED color schemes for white

 white - usually one narrow peak for blue, one wide smeared peak for yellow
 WW (warm white), CW (cool white) - different color temperatures, ratio of phosphor-converted yellow to original blue
 RGB - conventional, three narrow bands for R,G,B
 wavelengths of the triplets subtly differ
 RGBA - adds amber peak, for better flesh-color rendering for photography and indoor
 RGBW - adds white (warm or cool), for pastel color

whites

6500K - cool white
5500K - cool white
4000K - neutral white
3000K - "gallery white"
2200K - warm white

running phosphor too hot shifts LED towards blue; remote phosphor (not in direct contact in LED, typically coating on the enclosure) is immune

CRI

Color Rendering Index
usually used test strips TCS01..TCS08
extended variant uses TCS09, deep red below 600nm - important for skin tones, etc
even lamps with good CRI often have poor "R9" rendering [ref]
sample profiles: https://www.waveformlighting.com/tech/cri-ra-test-color-samples-tcs/

USA: CRI usually refers to CRI(R1..R8) - aka "general CRI" or CRI(Ra)
EU/Asia: usually CRI(R1..R14) - aka extended CRI, CRI(e), or CRI(Re)

common multicolor combinations

colors

 RGB (well duh) - rich colors
 RGBA - with amber/yellow, for warm and flesh tones
 RGBI - with indigo LED - eg. 622/518/468/450nm
 also RGB+intensity, 4-channel control of 3 color channels; can also be RGBW where I is for intensity of the white (can't be simple, can it be?)
 RGBI-L - with indigo and lime (568nm)

colors with white

 RGBW/RGBNW/RGBWW/RGBCW (with white/neutral shite/warm white/cool white, for pastel tones)
 RGBAW or RGBWA - amber+white
 RGBAW+UV amber+white+ultraviolet, "HEX LED" [ref]
 RGBWWCW - with cold and warm whites, "5-in-1"

whites

 WWCW - warm white with cool white, adjust color temperature by their ratio
 AWB - amber,white,blue - white tones

Additional colors to RGB

 A - amber, adds yellow for richer warm colors
 I - indigo, 450nm, adds coverage of blue
 L - lime, 568nm (566..569), wide peak, phosphor-converted
 WW,NW,CW - warm/neutral/cool white - "base" for pastel colors, together for adjustable color tempeature by ratio
 UV - for fluorescence effects, typ. 395nm

lime makes cool colors more vibrant
near-UV (deep blue?) makes most fabrics more saturated in color
RGBA gives warrm tones and enhances red colors (brick facade)

food illumination whites

special white hues for illumination of different kinds of merchandise, engineered spectral characteristics
https://cz.mouser.com/new/lumileds/lumileds-luxeon-freshfocus-led/
https://cz.mouser.com/pdfdocs/lumileds-freshfocus-brochure.pdf
 produce - more blue (fresher look), improved red, continuous spectrum (natural colors)
 peak 455 (0.78), valley 485 (0.27), slight bump in increase at 500..570, peak 630 (1), taper to 780
 bread, pastries - less blue, more yellow/orange (warmer look)
 peak 455 (0.35), valley 480, peak 620, taper to 780
 red meat - less blue (warmer look), better reds
 peak 455 (0.33), valley 485 (0.1), slower up to 570 (0.3), peak 640 (1), taper to 780
 marbled meat - more blue (fresher look), more green for whiter light, less yellow for cleaner white, better reds
 peak 455 (0.8), valley 485 (0.2), peak 530 (0.4), valley 575 (0.3), peak 650 (1), taper to 780
 fish - more blue (cooler white), less red (fresher effect)
 peak at 455 (1), valley at 485 (0.4), peak: 540 (0.45), valley 590 (0.38), peak 620 (0.4), slow taper to 780

plant growth LEDs

 "Petunia" grow lights, general purpose: 656nm (red), 3000K (white), 455nm (blue)
 "Petunia" grow lights, high efficiency/seedling/vegetative: 656nm, 450nm

 Luminus horticulture LEDs: 450..460nm peak, then wide flat peak 640nm (600..700)

https://cz.mouser.com/new/Luminus-Devices/luminus-hortilum-cob-leds/
280nm         reduces photosynthesis quantum yield, UVR8 photoreceptor pathway, used to increase THC in cannabis
315..400nm    promotes pigmentation, thickens leaves, maybe harms insects
440..470nm    chlorophyll peaks 439,469nm; most efficiently absorbed, promotes vegetative growth
510nm         quantum absorption in green spectrum(?), little in yellow
610nm         no chlorophyll effect, absorbed by phycocyanin - initiates photoperiodism (onset of flowering)
640..660nm    chlorophyll peaks 642,667nm; speeds up germination, flower/bud onset; 660nm most vital for flowering
690nm         unclear, some benefit maybe?
720..740nm    Emerson Enhancement Effect - red+far red together increase photosynthesis rate
1000..1400nm  no known activity, just heat

vision wavelengths, meltopic photoreceptors

[ref]
 photopic - max at 555nm, color vision
 scotopic - max at 507nm, night-vision
 meltopic - max at ~450nm, non-imaging, melatonin suppression

COLORS

common LED wavelengths

phosphor-converted ("PC")

 white (lots of color temperatures, different CRIs)
 PC amber - broad peak at 590-600nm, half-width between 560..640
 lime - broad peak at 540nm, half-width between 505..620, sometimes small (10%) peak at 450nm
 mint - like lime, with additional 30-50% peak at 440 or 450nm
 converted green - small peak at 425nm (20%), peak at 520nm, half-width 485..585 - high brightness for projection
 horticultural - peak at 450nm (~80%), peak at 640-650nm (100%), sometimes peak at 530nm

 whites, usually have:
 driving peak at 450..455 nm
 for ordinary lousy blue-yellow (CRI 70), secondary phosphor peak at 550..580nm (shorter more green for higher color temp, longer more yellow for lower color temp)
 for better color rendering (CRI 80) secondary phosphor peak at 590 to 615m (shorter more orange for higher color temp, longer more red-orange for lower)
 for high color rendering (CRI 90) also tertiary peak or bump around 550 nm (green) and secondary peak at 630nm (bright red)
 ice blue, 455nm peak, 0.5 peak at 510nm

Standards for machine vision:

 UV:    365nm,395nm
 blue:  470nm
 cyan:  505nm
 green: 530nm
 amber: 590nm
 red:   625nm
 IR:    850nm, 940nm

RGB

LED strip: 624,518,471
RGB LEDs:  624,525,470
           625,528,470
           627,538,476

most common:
blues:  470nm,   some 465,480,485, rare 458,453
greens: 525-535, some 518,525,528,530,538,540
reds:   624-627, some 605,620,630,

colors

https://www.ledtuning.nl/en/about-colors
 UV - displays white fluorescence of some LED materials
 ! 365nm - strongest fluorescence, UV curing
   380nm - almost no longer visible
   385nm - twilight purple, deep red blur
 ! 395nm - deep royal purple
 violet - 400..450
   400nm - more twilight than pure violet
 ! 405nm - very common, pure violet, longer-wavelenght UV curing
   415nm - bluish-violet
   420-430nm - violet
   436nm - deep blue
 blue - 450..500
   440-460nm - royal blue
 ! 450nm (455,457,458...) - "pure blue", royal blue, or indigo - in RGBI lamps, remote phosphor applications
 ! 451nm - "royal blue"
   450,455nm - "dark blue", in plant grow lights
   460nm - dark blue, "dental blue" matching camphorquinone photoinitiator
   465nm - common in white LEDs
 ! 470nm - most common standalone and RGB LED blue, white LEDs
   475nm - common standalone blue, a little azure
   465-485nm - blue
   480,485,488nm - common standalone blue, more azure
   490nm - light sky blue
   495nm - a little sky blue
 green - 500..570
   490-510nm - cyan
   505nm - turqoise/cyan
   510nm - greenish turqoise - "pure green" in RGB
   520nm - "pure green"
 ! 525nm - very common green, "pure green"
 ! 528nm - "true green", pure emerald green
   520-540 - green
   540nm - "true green", emerald green
   562nm - pure green
 ! 568nm - very common green, "bright green", "lime green", "lime" (also phosphor-converted, pc-L)
 yellow - 570..590
   572..575nm - also common, yellow-green
   575nm - lemon yellow, slightly greenish
   580nm - pure yellow
 ! 587..590nm - very common yellow
 ! 590nm - "natrium yellow", "amber" (also phosphor-converted, pc-A)
   585-600 - amber
   593..596nm - amber, also common
 orange - 590..610
   600nm - amber-orange
   601..610nm
   610nm - pure orange
 red - 610..780
   614-624nm - red-orange
   617nm, 620nm - clear orange-red
   623nm - red
   627nm - red
   624-634 - red
 ! 633..635nm - common range, bright red, "super red"
   640,645nm - bright red
   645nm - "photo red", in grow lights
   656nm - "hyper red", in grow lights
   660nm - "deep red"
   660nm - pure red
   655-675nm - deep red
   680nm - pure red
   700nm - deep red, low brightness
   720nm - far red
   720-750nm - far red
   740nm - "far red"
   750nm
 IR - 780...
   800nm
   808nm - common IR lasers, nightvis illuminators
 ! 850nm - very common; telco laser wavelength, multimode fiber-optic wavelength, increased dispersion/scattering
 ! 860nm - most common IR illumination, visible as weak red glow of the chip
   870..890nm
 ! 940nm - common IR illumination, eye-invisible
   950nm - common
  1020nm
  1050nm
  1064nm - Nd:YAG laser, nightvis SWIR illuminators
  1200nm
  1300,1310nm - common in telco lasers, fiber-optic wavelength with lowest dispersion, multimode/singlemode fibers
  (1450nm)
  1550nm - lidar, cosmetics/dermatology, SWIR nightvis illuminators; common in telco lasers, "eye-safe", singlemode fiber, lowest attenuation, wavelength of erbium-doped fiber amplifiers
  1650nm
  1720nm

sample vendor

   1300-1600K   pink
   1600-2000K   yellow
   2500-3500K   warm white
   4000-5500K   natural white
   6000-6500K   pure white
  10000-15000K  cool white
  20000-25000K  super cool white
  30000-35000K  cold white
  25000-35000K  ice blue

  400-840nm     full spectrum 1 (red-blue for plants)
  400-840nm     full spectrum 2 
  400-840nm     full spectrum 3
  400-840nm     full spectrum 4
  400-840nm     full spectrum 5
  380-840nm     sunlight

  440-450nm     royal blue
  460-465nm     blue
  480-485nm     cyan-blue
  495-500nm     cyan
  520-525nm     green (emerald)
  590-595nm     yellow
  595-600nm     amber
  600-605nm     orange
  620-625nm     red
  660-665nm     deep red
  740nm         IR
  850nm
  940nm

microscopy fluorescence excitation

https://www.coolled.com/product-detail/led-wavelengths/
365
380
400
425
440
470
490
500
525
535 - wide peak
550 - wide peak
565 - wide peak
585 - wide peak
595
615
635
660
700
740
770

optogenetics

https://www.prizmatix.com/Optogenetics/Prizmatix-in-vivo-Optogenetics-Toolbox.htm
 405nm - violet     - activate various Opsins with Violet activation spectrum
 460nm - blue       - activate Channelrhodopsin (ChR1, ChR2)
 500..580nm - lime green, 90nm half-width peak - activate Archaerhodopsin (Arch) or other Green light activated opsins in optogenetics experiments with freely moving mammals
 520nm - green      - activate Archaerhodopsin (Arch)
 625nm - orange-red - activate or inhibit Red shifted opsins (Jaws, Jaws-ER2)
 655nm - deep red   - activate or inhibit Red shifted opsins

fiber optics LED/laser wavelengths

 -OH group vibration attenuates at 1380nm (also less at 950 and 720nm)

 850nm -  770..920  - 3.5-2.5dB/km loss, common for short 100..500m distances with multimode fibers
1310nm - 1270..1370 - lowest dispersion (zero group velocity dispersion), single and multimode fibers, 0.35-0.5dB/km loss, cheap simple intensity-modulated systems for shorter distances
1550nm - 1500..1610 - fiber optics, lowest attenuation, singlemode fibers, 0.2dB/km loss, eye-safe
                      Er-doped amplifiers peak at 1530,1550nm

SFP transceivers: http://www.fiber-optic-solutions.com/single-mode-sfp-vs-multimode-sfp.html
 multimode (850?) - black
 1310nm - blue
 1490nm - purple
 1550nm - yellow

singlemode cable - usually yellow
multimode cable - usually orange

VCSEL laser - multimode, cheap
edge-emitting laser - Fabry-Perot, singlemode, more expensive design


Yb3+-doped silica laser: pump at 840 and 975nm
1020nm for pumping praseodymium fiber amplifiers
1140nm for pumping thulium-doped fluoride fiber upconversion lasers

common telco laser/LED wavelengths
850nm
1300nm
1310nm
1550nm

longer-wave IR LEDs

1020nm, 1060nm, 1300nm,1450nm,1550nm,1650nm
 Ice Detector/ Sensor
 Photoelectronic Switch
 Moisture Sensor
 Methane Gas Detector
 Optical Equipment

SWIR illuminators

808nm (NVG)
1064nm (SWIR)
1550nm (SWIR, eye-safe)

free-space optics communications:
http://www.fsona.com/product.php?sec=compdiff
808nm systems are low-power (safety), have low fog-penetration margin

ultraviolet LEDs

most commonly used for fluorescence, disinfection, UV curing
the shorter wavelength the higher the price per watt
in ultraviolet polymerization, shorter wavelengths are usually better absorbed by the photoinitiator (better surface cure, worse depth cure)
shorter wavelengths are also better for disinfection/sterilization and for photocatalysis

UVC (280-100nm)

sterilization, fluorescence analysis
 265nm
 275nm
 285nm

UVA (400-315nm)

UV curing, fluorescence analysis
 365nm     a "decent" ultraviolet; weaker whitish light from fluorescence of diode materials, can be suppresed with a filter (eg. ZWB2 glass)
 385nm     in-between for 365 and 405nm
 405nm     most common, also available as lasers
 410nm     cheaper variant of 405nm, for some uses still good

applications by Rahn

 365nm     most common for curing adhesives
 385nm     most common curing for inks/coatings in Europe
 395nm     most common curing for inks/coatings in US
 405nm     most common curing for 3d printing, dental

Laser diode wavelengths

    375nm       Thorlabs
!   404/405nm   purple/violet/UVA; watt-class powers available; some laser pointers; GaN; some use frequency-doubled 808nm laser diode
!   445/450nm   royal blue; common in cheap high-power cutting/engraving lasers; some laser pointers; InGaN
    465/470nm   blue (Nichia)
    473nm       DPSS, doubled 946nm of Nd:YVO4
    488nm       mint-blue (Sharp); some laser pointers
    505nm       mint-green
    515/520nm   green; atypical green laser pointers, more expensive than 532nm doubled; Nichia, OSRAM
!   532nm       green (DPSS, Nd:YAG doubled); common laser pointers, poor low-temperature performance
    561nm
    577nm       yellow; medical lasers for vascular skin conditions
    589nm       yellow; some laser pointers; doubled 1178nm diode
    593.5nm     orange; some laser pointers; DPSS, summed 1064nm and 1342nm of Nd:YVO4
!   633/635nm   red; appears brighter per mW than 650nm
!   637/638/639nm red; similar to 630nm, higher powers
    640/642nm   red
!   650nm       red (plentiful)
    658nm       red
    660nm       red
    671nm       deeper red, uncommon, DPSS (higher beam quality)
    685nm       red
    690nm       deep red
    705nm
    730nm
    755nm       IR; medical
    761nm
    770nm
    780nm       IR
    785nm       IR; higher powers, common
    795nm
!   808nm       IR (plentiful); common as night vision illuminators, medical, high-power modules for pumping Nd:YAG crystals; GaAlAs
    816nm/820nm
    828/830nm   IR; common-ish, high power
    850/852nm   IR; telco laser; black SFP modules, multimode; 770..920nm band, 3.5-2.5dB/km loss, common for short 100..500m distances with multimode fibers
    880/895nm   IR; uncommon
    904/905nm   IR; lidars, cheap, output power limited by eye safety, 100m range; common as pulsed high-power
    915nm
    935nm
    940nm       IR; higher power
    960nm       IR; higher power, uncommon
    976nm       IR; single-frequency (longitudal-mode) available
    980nm       IR; higher power; medical, spider veins, good fat tissue absorption
   1060nm
   1064nm       IR; matches Nd:YAG laser; higher power
   1083nm
!  1310nm       IR; telco laser; blue SFP modules; 1270..1370nm band, lowest dispersion (zero group velocity dispersion), single and multimode fibers, 0.35-0.5dB/km loss, cheap simple intensity-modulated systems for shorter distances; high power available
   1425nm
   1436nm
   1450/56/80nm
   1490nm       IR; telco laser; purple SFP modules
!  1550nm       IR; automotive lidars, eye-safe so high powers allowed; telco lasers; yellow SFP modules; fiber optics, lowest attenuation, singlemode fibers, 0.2dB/km loss; high power available
   1575nm
   1625nm       IR
   1650nm       IR
   1940nm
   1950nm       IR; surgery diode lasers, seems to be an ideal wavelength for laser microvascular anastomoses
   2000nm
   3850nm       MWIR, Fabry-Perot Quantum Cascade
   4040nm       MWIR, Fabry-Perot Quantum Cascade
   4050/4055nm  MWIR, Fabry-Perot Quantum Cascade
   4060/4065nm  MWIR, Fabry-Perot Quantum Cascade
   4..5um       MWIR, Distributed Feedback Quantum Cascade
   5..6um       MWIR, Distributed Feedback Quantum Cascade
   6..7um       MWIR, Distributed Feedback Quantum Cascade
   7..8um       MWIR, Distributed Feedback Quantum Cascade
   8..8.1um     MWIR, Distributed Feedback Quantum Cascade
   8..9um       MWIR, Distributed Feedback Quantum Cascade
   8450nm       MWIR, Fabry-Perot Quantum Cascade
   9..10um      MWIR, Distributed Feedback Quantum Cascade
   9150nm       MWIR, Fabry-Perot Quantum Cascade
   9550nm       MWIR, Fabry-Perot Quantum Cascade
   10..11um     MWIR, Distributed Feedback Quantum Cascade

1350nm wavelength has lowest solar background noise, investigated for lidar use [ref]

laser diode mounts

   TO-5, "9mm"     thick base press fit; 9.0mm diameter base, 6.7mm dia can, "big laser diode", "bigger small transistor"; variety of lenses; common also for photosensors/photodiodes
   TO-18, "5.6mm"  thick base press-fit; 5.6mm diameter base, 3.5mm dia can, "small laser diode", very common for low powers; "small transistor"; common also for photosensors/photodiodes
   TO-38           3.8mm diameter base, flattened on both sides to 3.2mm; 2.5mm dia can
   TO-46           4.6mm diameter can (MISNOMER?!? TO-46 is a variant of TO-18!); variety of lenses
   TO-56           can; 5.6mm diameter base, 3.5mm dia can
   TO-72           TO-18 with 4 leads
   C-mount
   F-mount      flat, two screws to base

   variants:
   TO-3:  flange mount on heatsink, two screw holes TO-3
          TO-41: solder pads with holes instead of pins; TO-41 = TO-204-AB
          TO-204: JEDEC family designation; eg. TO-3 = TO-204-AA

   TO-5:  8.9mm diameter, 6.3mm high cap TO-5
          TO-39,9,16,42: differ in lead lengths; TO-39 = TO-205-AD
          TO-12,33: 4-lead; TO-12 = TO-205-AB, TO-33 = TO-205-AC
          TO-75: 6-lead
          TO-76,77: 8-lead
          TO-78,79,80,99: 8-lead, 4.45/3.81/2.41mm high cap; TO-78/99 similar to TO-205-AF
          TO-74: 10-lead
          TO-96,97,100: 10-lead, flatter cap
          TO-73: 12-lead
          TO-101: 12-lead, flatter cap
          TO-205: overarching family, JEDEC, eg. TO-5 = TO-205-AA

   TO-8:  12.3mm diameter cap, 7.62mm high cap; common for optical sensors; TO-8
          TO-233: JEDEC family designation; eg. TO-8 = TO-233-AA

   TO-18: 4.7mm diameter cap, 4.83mm cap; common for optical sensors; TO-18
          TO-46,52: differ in can height, 3.3mm/1.9mm; TO-46 = TO-206-AB
          TO-71: 8-lead
          TO-72: 4-lead; TO-72 = TO-206-AF
          TO-206: JEDEC family designation; eg. TO-18 = TO-206-AA

   TO-66: flange mount on heatsink, two screw holes, 1.9mm base plate, smaller TO-3 TO-66
          TO-123: 1.02mm base plate; TO-123 = TO-213-AB
          TO-124: 2.6mm base plate; TO-124 = TO-213-AC
          TO-213: JEDEC family designation; eg. TO-66 = TO-213-AA

laser module diameters

    4mm   cheapest "pointer" modules
    9mm   less common
   12mm   common chrome-plated cylindrical modules; typ. 40mm long; typ. M9x0.5 lens
    

DEVICES/MATERIALS

common SMD LED sizes

 5730
 5050 - most common LED strip
 3535
 3528
 3020
 2835
 1515
 1206, 0805, 0603, 0402

phosphors

 white: warm/cool white, ratio of phosphor to driving blue
 lime: 568nm peak, phosphor-converted ("pc-L") - cool colored objects appear more vibrant
 amber

phosphor compositions

https://www.yujiintl.com/phosphor.html
YAG:Ce         - most common for white LEDs, good chem-thermal stability, degrades at higher temp; excitation at 455nm, emission at 550nm
LuAg:?         - emits at 510..540nm, comparable to YAG, green, use with nitride red
nitride red    - emits at 600..660nm, excit. with 400..460nm, for white LEDs and plant growth lamps; violet LED, phosphate blue, beta-SiAlON gives full-spectrum high-CRI white
oxynitride red - emits at 500..650nm (max 615nm), excit. 455nm
nitride green  - emits at 525..545nm, narrowband; blue LED+SiAlON green for LCD backlights
KSF yellow     - emits at 631nm, narrow peaks, excit. 455nm
infrared       - emits at 710..730nm (max 712nm), excit. 455nm, blue 460nm + red 660nm + IR for best plant growth
Sr[Li2Al2O2N2]:Eu2+ - red, SiAlON, 
(Ba,Sr)3N2:Eu  - amber, for pc-amber LEDs; 595nm, ext.quantum efficiency 30-40%
Sr(LiAl3N4):Eu2+ - red, narrowband, Lumileds
yellow-green   - in white LEDs
red            - in white LEDs, narrowband or wideband (less efficient)

silicate phosphors - lower lifetime, very bright, for cellphones

LED phosphors for sale: https://phosphortech.com/products/led-phosphors/
  $215..$450/100g, yellows
  $450/100g, greens
  $1120/100g, reds

IR upconversion phosphors

phosphors: https://maxmax.com/phosphorsdyesandinks/infrared-phosphors-dyes-and-inks/infrared-up-conversion-powder
used with 940..980nm laser
IRUCG    948..983nm -> 552nm   - most efficient
IRUCG-EX 948..983nm,1510nm,1550nm,1600nm -> 552nm
IRCUR    980nm -> 660nm
IRUCY    948..983nm -> 575nm
IRUCB    980nm -> 445nm
IRSPG    700..1500nm -> 490nm - needs charging with visible light

antistokes phosphors hard to manufacture, low-availability, used in security applications

xray phosphors

Gd2O2S:Tb - green, 7.5g/cm3, 8..80 kVp (540..550nm, tiny peak at 490nm)
Y2O2S:Tb  - blue-white, 5g/cm3, 30..100 kVp (blue-white, 540..550nm peak, more peaks in 400..500nm)
both $44/10g

UV phosphors:
UVSWR    270nm -> 610nm, 10nm particles
UVSWG    250..270nm -> 525nm
UVSWB    293nm -> 480nm, 5nm particles
UVLWR    360nm -> 628nm
UVLWG    380nm -> 518nm
UVLWB    365nm -> 450nm
all $44/5g
UVInkLWRSWG-1   254nm -> green, 365nm -> red

static electricity ESD damage

LEDs sensitive to ESD
diagnosed by forward voltage at very low current (e.g. for 260nm UV LED fail is Vfwd below 4.0V at 500 µA)

materials

 450..530 - GaN - 450..475 for white LED with phosphor, 520..530nm green for traffic lights
 565..645 - AlInGaP - traffic light amber 590nm, red 625nm; 565nm lime and 605nm orange available but limited

SMART LEDS

Neopixel/WS2812b alternatives

 Singlewire (asynchronous)

input DI (data in), output DO (data out); relies on precision bit timing
 WS2812
 WS1012 - possibly a misnomer for WS2812
 WS2811,WS2811S - driver chip, no LEDs, 800kHz clock max, max.12V input, constant-current drive, DIP8,SOIC8(-S)
 WS2812 - 6-pin
 WS2812b - 4-pin
 WS2812b 3535 - smaller version of the original
 WS2812d - 8mm LED
 SK6812 (high pulse >440ns (orig. 625ns), PWM 1.1kHz (orig 430Hz) (comes also in rgbw) - may be less abuse-sensitive than WS2812?
 SK6812 mini, 3535 size
 P9823 - controller chip, WS1012 protocol, PWM up to 800 kHz
 PD9823 - 5mm(-F5)/8mm(-F8)/5x5SMD(-5050)mm LED, -5050 pinout same as WS2812
 PL9834 - 5/8mm LED, power in series directly from rectified AC (instead of parallel from a buck converter), uncommon
 APA106 - 800kHz PWM, round-hat LED 5mm (-F5)/8mm (-F8), different timing than APA104, slower (600kHz?)
 XT1511 - Jercio (brand), uncommon; versions -RGB, -RGBA, -WWA


WS2812

       -----              -----              -----            --flat
   DO |/    | GND    GND |/    | DO       R |/    | +5V     /    |---- |--   DO
   DI | ( ) | +5V        | ( ) |          G |     | SET    |     |---- |---- GND
 3.3V |     | nc      DI |     | +5V      B |     | DI     |     |--   |---  +5V
       -----              -----         GND |     | DO      \    |--   |--   DI
      WS2812             WS2812B             -----            ---
                                            WS2811          round
SET: 800kHz(nc), 400kHz(+5V)


APA106


SK6812


PD9823

virtually identical to WS2812 [ref]




 Two-wire (separate CLK)

input CI/DI (clock/data input), output CO/DO (clock/data output)
 WS2813
 APA102 - bus max 20MHz, (superceded by SK6822), 19.2kHz/582Hz PWM
 APA104
 APA107 - bus max 30 MHz; 9kHz PWM; direct replace of APA102
 HD107S - bus max 40 MHz; 26+ kHz PWM; direct replace of APA102
 SK6822 - dual data lines (comes in RGBW, RGBWW, WWA, and RGB 3535-size versions, higher PWM frequency than WS2812b)
 SK9822 - bus max 15 MHz; 4.7kHz PWM
 LPD8806 - driver chip, no LEDs



APA102

APA102 (presumably also 104, 106) - 32bit (111+global bright(5bit)+RGB)
 two PWM superimposed, 19.2kHz for color, 582Hz for global brightness
 chain needs start frame of 32 (or more) zeroes, first 1 then acts as a start bit, LEDs update immediately after their frame is received
 needs end frame of n zeroes where n>= number of LEDs in chain divided by 2
 clock can be as high as 4MHz, maybe faster (20 MHz?)
 https://cpldcpu.wordpress.com/2014/11/30/understanding-the-apa102-superled/
 staggered update
 APA102=square aperture, APA102C=circular

 ----- DI |/    | DO CI | ( ) | CO GND |     | +5V -----


SK9822

      -----
  DI |/    | +5V
  CI | ( ) | DO
 GND |     | CO
      -----

similar to APA102 [ref]
 4.7kHz PWM
 current regulation for global brightness
 global update
 minor incompatibility with APA102 protocol, can be made compatible by sending all-zero stop frame



 MEDICAL


 SAD therapy

10,000 lx, 5000K temperature, half-hour
min. 2,500 lx
lx-to-watt calculator: https://www.rapidtables.com/calc/light/lux-to-watt-calculator.html

1 lux=1 lumen/m2
1 cd/m2 = 1 lux = 1 nit

1 cd/m2 = 8 lux on light pavement, 14 lx on average, 18 lx on dark pavement
https://books.google.cz/books?id=ppBgBqWIdCgC&pg=PA20&lpg=PA20&dq=cd/m2+lux&source=bl&ots=3ynXa9_yqp&sig=ACfU3U3BOtnI-1nHaFfv-Wg_wa6AtQQV-w&hl=en&sa=X&ved=2ahUKEwj_uMGhgqDmAhWcQ0EAHWBcAE84ChDoATAFegQIChAB#v=onepage&q=cd%2Fm2%20lux&f=false ;
In Belgium, the most commonly encountered road pavements were bituminous asphalts (R3, with Qo from 0.07 to 0.10 cd/m2/lux) and porous asphalts (R2, with 0.05 to 0.08 cd/m2/lux)
road brightness at least 1-2 cd/m2
https://spie.org/samples/TT63.pdf

diffuse reflectance: cd/m2/lux

LED: 2500lx on 1 m2 =  28W  (90lm/W)
lightbulb           = 166W  (15lm/W)
halogen             = 125W  (20lm/W)
metalhalide         =  29W  (87lm/W)
highpres sodium     =  21W (117lm/W)

LCD panels: usual brightness???



 oximeters

dual-wavelength sensing, difference for absorption between oxy and deoxyhaemoglobin
660/880nm
660/905nm     less common
660/940nm

7 or more wavelengths is becoming more standard - measure haemoglobin, oxygen content, carboxyhaemoglobin, methaemoglobin

660nm - oxyHb absorbs MUCH less than deoxy
800nm - both equal
800+nm - deoxyHb absorbs slightly more than oxyHb, diff rough equal from about 850-900nm

carboxyHg causes false high reads of SpO2
graph for O2Hb, HHb, COHb, MetHb: https://ars.els-cdn.com/content/image/1-s2.0-S095461111300053X-gr2.jpg

AS7263 NIR: 610, 680, 730, 760, 810, 860nm, each 20nm wide




 SENSORS, IMAGING

section to be moved to own notes


 spectral sensors

AS726x: 6 wavelengths, on-chip filter
AS7262 vis: 450, 500, 550, 570, 600, 650nm, each 40nm wide (half-width)
AS7263 NIR: 610, 680, 730, 760, 810, 860nm, each 20nm wide
AS7341: 11-chan (clear, flicker, NIR, 6x ADC, input mux) 210czk(Mouser)
     F1: 410+-10nm/29nm halfw
     F2: 440+-10nm/33nm
     F3: 470+-10nm/36nm
     F4: 510+-10nm/40nm
     F5: 550+-10nm/42nm
     F6: 573+-10nm/44nm
     F7: 620+-10nm/53nm
     F8: 670+-10nm/60nm



 night vision


common IR illuminators

808nm
915nm
(also 940nm)

808nm (NVG)
1064nm (SWIR)
1550nm (SWIR, eye-safe)


LEDs:

(805nm)
850nm
940nm

https://www.pulsar-nv.com/glo/support/night-vision-technologies/77
common illuminator powers:
30..100mW for LED
10..50mW for lasers



photocathodes

https://www.azooptics.com/Article.aspx?ArticleID=1058
(minimizing parasitic sources of NIR light to avoid nightvis saturation in cockpits)
gen.III - from 500nm (present) or 600nm (old, 1990's) to just over 900nm


night sky - strong NIR light at 920..1000nm, up from 640nm, tapering down to way beyond 1100nm
luxmeters work between 380..780nm, need also bands 780..810nm (average, high-sensitivity of CCD/CMOS sensors) and 910..940nm (high-value of night sky, lower sensitivity)
GaAs photocathode 680..840nm, tapers to 900nm, next to zero at 920nm
CCD/CMOS sensitive most at 640nm, tapers slow to quite over 920nm

915/940nm lamps/lasers invisible on photocathode nightvis amp tubes

passive mode - advantage on image amplifiers; gen2+ tubes outside of cities need additional illumination



 thermal imagers

FLiR Lepton - 160x120 (earlier 80x60)
MLX90621 - 16x4, 120/25deg FOV, -20..+300 +-1c/3% °C, I2C, 3.3v, operating temp -40..+85c, 0.5..64 Hz
MLX90640 - 32x24, 55x37 or 110x75deg FoV (fixed), -40..+300 +-1.5 °C, I2C, 3.3v, operating temp -40..+85c, 0.5..64 Hz
MLX90641 - 16x12, 110x75deg FOV (fixed), -40..+300 +-1.5 °C, I2C, 3.3v, operating temp -40..+125c
AMG8833  - 8x8, 60deg FOV, 0..80 +-2.5 °C, I2C, 3.3v


 people sensing

AK9753   - presence sensor, 80' FOV, 4-quadrant photoelectric NDIR, I2C, 1.7..3.3v, dig.filt. 0.2..9.7 Hz


 singlepoint

MLX90614 - infrared thermometer, 5 or 35deg FOV, -70..+380c, body temp range accuracy +-0.2c, 0.5..64 Hz




 ROIC - Readout integrated circuit

Readout integrated circuit

FLiR offers ROIC chips, bias for low-bandgap p-on-n sensors, some for n-on-p
sensors InSb, InGaAs, MCT(== HgCdTe), QWIP, SLS(n-on-p?)

modes:
integrate-while-read
integrate-then-read
nondestructive read (only ISC0402)
https://www.flir.com/globalassets/imported-assets/document/flir-isc9803-specifications.pdf
https://www.flir.com/globalassets/imported-assets/document/flir-large-format-roic-brochure.pdf

electron wells (integration caps): 11.2 or 3.2 millions electrons (350 or 100 femtofarads?)
1 farad == 6.25e18 electrons

xray ROIC
https://www.flir.com/globalassets/imported-assets/document/17-0740-oem-cor-xray-datasheet-update_final_v1_web.pdf
with Se, CsI, Si, amorphous Si, GaAs, CdZnTe sensors






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