4波長高出力LED照明


  • 4-Wavelength LED Source with Stable and Repeatable Emission
  • LED Switching Controlled via Current
  • Choose from 14 LEDs
  • Liquid Light Guide and Microscope Adapters Available

LED4D067

4-Wavelength High-Power LED Source

Ideally Operated by
DC4100 or DC4104 Drivers

LED4B1

Adapter to Couple
Liquid Light Guides to
the 4-Wavelength Source

Internal View of a 4-Wavelength Source

Related Items


Please Wait
LED Options
Nominal
Wavelength
Color
(Click for Spectrum)
Min LED
Output Powera
365 nmUV85 mW
385 nmUV95 mW
405 nmUV290 mW
420 nmViolet95 mW
455 nmRoyal Blue310 mW
470 nmBlue250 mW
490 nmBlue50 mW
505 nmCyan170 mW
530 nmGreen100 mW
565 nmGreen Yellow106 mW
590 nmAmber65 mW
617 nmOrange210 mW
625 nmRed240 mW
660 nmDeep Red210 mW
  • このLEDを使用した4波長照明からの出力(非球面コンデンサーレンズの後で測定)
General Specifications
Operating Temperature Rangea0 °C to 40 °C (32 °F to 104°F)
Storage Temperature Range-40 °C to 70°C (-49 °F to 158 °F)
Dimensions (W x H x D)164 mm x 150 mm x 57 mm (Without Cable)
(6.46" x 5.91" x 2.24")
Front Aperture ThreadInternal SM2 (2.035"-40)
Weight1.6 kg (3.5 lbs)
  • 結露なし
Wavelength Combinations
 
365 nmXXXX          
385 nmXXXX          
405 nmXXXX          
420 nmXXXX          
455 nm    XXX       
470 nm    XXX       
490 nm    XXXX      
505 nm      XXXX    
530 nm       XXX    
565 nm       XXXX   
590 nm         XX   
617 nm           XX 
625 nm           XXX
660 nm            XX

波長の組み合わせ

各LED4Dには、単体のハイパワーLEDが4種類内蔵されています。右表に記載されている14種のLEDから4波長を選択して、お客様ご所望の4波長照明LED4Dを構成するために、下記の波長構成ツールをご用意いたしました。光学的な波長構成の都合から、同じ照明内で組み合わせることができない波長が存在します。波長構成ツールで各波長を選択いただく際、利用できない波長の組み合わせは、その下に続く各ドロップダウンメニューから除外されます。

全ての構成における波長の制約は、右の表の中に大まかに示されています。同じ4波長の照明の中に含めることのできない2波長の組み合わせはそれぞれ、灰色のセルに×印が表示されており、利用可能な組み合わせは緑色かオレンジ色のセルで示してあります。オレンジ色のセルは、残りの2つのLEDの選択にさらに制約が加わる波長の組み合わせであることを示しています。すなわち、LED4Dの3つの波長として、660 nm、617 nmと、590 nmまたは660 nm、617 nmと、565 nmを選択した場合、4番目の波長として455 nmより短い波長を選択することはできません。下記の波長構成ツールは、利用できない波長の組み合わせは実現できないように設計されています。

Legend
X
Unavailable Wavelength Combination
 
Available Wavelength Combination
 
Limited Combinations Availablea
  • LED4Dで565 nm、617 nmと660 nm、または590 nm、617 nmと660 nmの組み合わせを選択した場合、4番目の波長として455 nm以上の波長しか選択できません。

特長

  • 自由に設定できる4波長照明
  • LED電流制御によるスイッチと強度調整
  • ガス放電ランプやハロゲンランプよりも高い発光安定性と再現性
  • 可動部がないため、振動が発生しない
  • 冷却フィンが効率的に温度管理
  • 長寿命(詳しくは「LEDの仕様」タブをご覧ください)
  • Olympus、Nikon、Zeiss、Leica製顕微鏡の照明ポート用のアダプタ有り
  • 液体ライトガイド(LLG)への入射用のアダプタ有り

LED4Dシリーズの4波長の高出力LED照明は、最大4波長の高性能照明が必要な用途に適しています。この自由に設定できる照明では、4つの全てのLED出力を効率よく1つのコリメート光に結合します。LED4Dを4チャンネルLEDドライバDC4100またはDC4104と共にご使用いただくことで、LEDのスイッチングや個々のLED変調が可能な確実かつ汎用性の高い照明となります。この照明は振動を発生せず、操作が簡単で、長寿命であることが特長です(詳細については「LEDの仕様」タブをご参照ください)。

ハロゲンやガス放電ランプのような従来の照明と比較して、こちらの4波長照明には多くの利点があります。狭帯域発光なので信号対雑音比が高く、安定性も高く、長寿命です。取替え費用を抑え、定期的なメンテナンスが不要、さらに操作は簡単です。また、熱負荷が小さく抑えられているので、強制冷却やサーマルフィルタリングは不要です。動作波長や光強度を、ドライバDC4100またはDC4104(ともに別売り)のフロントパネル、あるいはUSB接続を通じて迅速に設定できるので、この照明は複数の波長の制御が求められる顕微鏡用途にお勧めの製品です。DC4100またはDC4104内の外部トリガ接続により変調することもできます(これらのドライバの詳細は こちらでご覧いただけます)。

こちらの照明に組み込まれているLEDは、大きな発散角に特長があります。システム内の光路はミラーによって誘導され、出力光が非球面コンデンサーレンズでコリメートされます。この光学系によって、単体のLEDに比べ、出力パワーは本質的に低減されます(右表参照)。当社では、波長合波用の光学素子を使用しない、高出力のシングルチャンネルのコリメータ付きLED照明もご用意しております。

アダプタ
液体ライトガイドまたは各社顕微鏡と共に4波長LED照明を使用する際のアダプタは、オプションでご提供可能です。これらのLED照明の出力開口部には、SM2の内ネジが付いています。Olympus、Nikon、Zeiss、Leica製の顕微鏡用のアダプタも、別途ご用意しております。このアダプタをお使いいただくと、4波長照明を顕微鏡の照明ポートに直接取り付けることができます(SM2シリーズの顕微鏡用アダプタを参照)。照明をOlympus製顕微鏡に取り付ける方法については、下に掲載されている動画をご参照ください。

もしくは、液体ライトガイド(LLG)用アダプタLED4B1を使用して、LED照明の出射光をLLGに入射させることも可能です。これによって、SM2ネジ付き出力ポートが、SM1内ネジ付き開口に置き換えられます。このアダプタには、LLGの開口部の中に集光するよう設計された、コリメート用光学素子が内蔵されています。LLGは、適切なLLG-SM1アダプタ(Ø3 mm口径のLLG用にはAD3LLG、Ø5 mm口径のLLG用にはAD5LLG)によって保持されます。これらのアダプタと当社の液体ライトガイドのより詳しい情報は、こちらでご紹介しています。

Liquid Light Guide Adapter
Click to Enlarge

アダプタLED4B1は、4波長LED照明からの出射光をLLG-SM1アダプタ内に保持されたLLGに入射するために使用されます。
Nominal
Wavelength
Color
(Click for Spectrum)
Minimum LED Output PoweraMaximum Current (CW)Forward VoltageBandwidth (FWHM)Typical Lifetime
365 nmUV85 mW700 mA4.4 V7.5 nm>10,000 h
385 nmUV95 mW700 mA4.3 V10 nm>10,000 h
405 nmUV290 mW1000 mA3.8 V13 nm100,000 h
420 nmViolet95 mW1000 mA3.5 V15 nm>10,000 h
455 nmRoyal Blue310 mW1000 mA3.2 V18 nm100,000 h
470 nmBlue250 mW1000 mA3.2 V25 nm100,000 h
490 nmBlue50 mW350 mA3.5 V27 nm>10,000 h
505 nmCyan170 mW1000 mA3.3 V30 nm100,000 h
530 nmGreen100 mW1000 mA3.2 V33 nm100,000 h
565 nmGreen Yellow106 mW1000 mA3.1 V104 nm50,000 h
590 nmAmber65 mW1000 mA2.2 V18 nm100,000 h
617 nmOrange210 mW1000 mA2.2 V18 nm100,000 h
625 nmRed240 mW1000 mA2.2 V18 nm100,000 h
660 nmDeep Red210 mW1200 mA2.5 V25 nm>65,000 h
  • このLEDを使用した4波長照明からの出力(非球面コンデンサーレンズの後で測定)

LED Spectra Chart

14 Pin Controller Connector

LED4Dにはフライングリードが付いており、その終端には4チャンネルLEDドライバDC4100とDC4104に対応する14ピンM16プラグが付いています。 下の表にあるLED A、LED B、LED C、LED Dは、短波長から長波長の順に、各光源に搭載されるLEDを示しています。

PinDescriptionComment
ALED1 Anode -
CLED1 Cathode -
ELED2 Anode -
GLED3 Anode -
JLED3 Cathode -
LLED4 Anode -
MLED1 1 Wire EEPROM I/ODo Not Use
NDGNGDo Not Use
ONot Connected-
PLED2 Cathode -
RNot Connected-
SNot Connected-
TNot Connected-
ULED4 Cathode
液体ライトガイド(LLG)アダプタの取付け

当社の4波長LED光源は、アダプタLED4B1を使用することによって、当社の液体ライトガイド(LLG)を取り付けることが可能です。 取付けの工程については、右の動画、および下記の説明文をご参照ください。

4波長光源に付いているSM2内ネジ付き出力ポートを4本のM2.5ネジを回して取り外します。 M2.5用のザグリ穴がLED光源の筐体上のタップ穴と合うように、LED4B1を4波長光源の出力部分の上に設置します。 LED光源に付いていたM2.5ネジを使って、アダプタを所定の位置に固定します。

SM1ネジ用LLGアダプタ(AD3LLGまたはAD5LLG、付属しておりません) をLED4D1のSM1ネジ切付き出力側ポートに取り付けます。そして、液体ライトガイドをアダプタに差し込みます。 0.05インチの六角レンチを使用してSM1ネジ用LLGアダプタの側面に止めネジを締め付け、液体ライトガイドの位置を固定します。


Posted Comments:
Alfredo Del Rio  (posted 2021-07-23 21:29:53.693)
Hi, The download for this LED Head is only the shell. We are planning to use only the internal optical components in a microscope we are designing. Can you provide a STEP file (or similar) of the internal assembly that I can import into SolidWorks? Thank you
soswald  (posted 2021-07-28 04:51:20.0)
Dear Alfredo, thank you for your feedback. Please contact your local tech support team so we can discuss your application in more detail and provide the necessary assistance.
Peng Jun  (posted 2021-04-12 14:52:29.56)
Hi, may I select two IR LED source (780nm and 880nm)to be integrated within your 4-Wavelength LED Source? Please let me know. Thank you!
MKiess  (posted 2021-04-14 08:12:42.0)
Dear Peng, thank you very much for your inquiry. We have the possibilities to manufacture, this 4-wavelength high-power LED source, with further wavelengths here as a special design. I have contacted you directly to discuss further details with you.
Atanu Bag  (posted 2020-11-12 20:58:57.98)
Hi, can we use one wavelength at a time?? Or, all channel (4 wavelength) will be activated during operation.
wskopalik  (posted 2020-11-13 04:03:43.0)
Dear Atanu, Thank you very much for your inquiry! Yes, you can also just use one wavelength at a time. Each LED can be individually controlled on the LED drivers. There is just one limitation on the DC4100 driver. All activated LEDs are controlled by the same modulation signal on this driver but can be individually deactivated. For the DC4104 controller however, each LED is controlled by a separate modulation signal, all of which are provided through a single, included cable. So if you want to control each LED individually by external modulation the DC4104 would be the best solution. I will contact you directly to provide further assistance.
user  (posted 2020-06-11 11:42:07.233)
Hi! I am really interested in buying the 4-LED module with wavelength 470 nm, 530 nm, 590 nm, and 625 nm. For my application, the spectral bandwidth needs to be smaller than 10 nm so I wonder in front of each LED we can insert a bandpass filter. This filter will be before the dichroic mirror so it only affects each individual LED. I am completely aware that the intensity will be reduced. I would prefer to order it with this modification. However, I am happy to do this change by myself. Any feedback?
dpossin  (posted 2020-06-15 06:41:16.0)
Dear Customer! Thank you for your feedback. Unfortunately due to the limited space inside the LED4D housing we can not apply any additional optics in front of the LEDs.
gmcnama2  (posted 2018-10-31 09:33:15.147)
Dear ThorLabs, with respect to your LED4D067 = 4-wavelength high power LED source (aka "4LED"), can: * LEDs be moved by me between two 4LED sources? ** if no, can I custom specify what LEDs go in each of two units ... and work with you to specify beam combiners? * do you offer a "merge module" to combine outputs of two 4LED sources (before going to LLG or back of microscope)? thanks, George
nreusch  (posted 2018-11-09 10:08:24.0)
This is a response from Nicola at Thorlabs. Dear George, thank you for your inquiry! We can offer to change the LED configuration of the 4-wavelength LED source as service, but we strongly recommend sending the source to us, as we need to readjust the LED source. Unfortunately, we do not offer a universal merge module, but you might be able to use a beam combiner for this purpose. Please contact your local Tech Support team for further information.
xuy  (posted 2018-09-06 01:42:17.573)
Hi, may I select a IR LED source (730nm-970nm)to be integrated within your 4-wavelength high power LED source? Please let me know. Thank you! Best regards, Yingshun XU
swick  (posted 2018-09-12 04:10:04.0)
This is a response from Sebastian at Thorlabs. Thank you for the inquiry. We can offer customized 4-Wavelength High-Power LED Sources. I contacted you directly to provide assistance.
fs417  (posted 2018-06-28 11:01:55.777)
I was wondering whether it is possible to have an excitation filter installed directly inside the LED combiner before the combining dichroics. Especially the 565nm LED is extremely broad, so I would like to filter it beforehand.
nreusch  (posted 2018-07-04 09:32:17.0)
This is a response from Nicola at Thorlabs. Thank you very much for your inquiry. Unfortunately, the effort for this modification would be very high. I will contact you directly in order to check whether there might be an easier alternative for your application.
mauro.biagi  (posted 2017-11-16 14:49:40.0)
What about rise-fall times of these LEDs?
mvonsivers  (posted 2017-11-21 03:40:18.0)
This is a response from Moritz at Thorlabs. Thank you for your inquiry. Unfortunately, we do not specify the rise/fall times for our LEDs, therefore, we can not guarantee any values. In general, you can expect the rise/fall time to be shorter than 2-3 µs. We will contact you directly for further assistance.
l.volkers  (posted 2017-03-03 06:05:12.103)
Could you please provide the maximum light irradiations (in mW/mm2) for the following wavelengths: 470 nm, 530 nm, 590 nm, 625 nm? I want to incorporate the LED source in an Olympus BX51WI microscope with a 10x and 40x objective and want ot be sure that I can cover a 0 to ~15mW/mm2 irradiation range. Thanks
swick  (posted 2017-03-07 03:09:38.0)
This is a response from Sebastian at Thorlabs. Thank you for the inquiry. Unfortunately, the objectives you are using are not mentioned so we can not apply this measurement. We could send you a loan device of LED4D for testing purposes. Unfortunately, you did not left contact details on the feedback form. Please contact europe@thorlabs.com, for further assistance.
eddie.ross  (posted 2016-10-03 11:45:08.86)
Could you please provide information about the RGB mixing ratios / drive currents in order to achieve white light output from this LED source? Thanks
swick  (posted 2016-10-04 04:02:42.0)
This is a response from Sebastian at Thorlabs. Thank you for the inquiry. Unfortunately, the four wavelength LED source is not designed to emit white-light based on superimposing four LEDs. The spatial profile of intensity is non-constant, which makes it impossible to achieve proper white-light over the full clear aperture. I will contact you directly to discuss alternatives.
thobra  (posted 2016-09-26 06:21:29.427)
Hi. I am interested in knowing wheather this LED unit may be controlled by micromanager (www.micro-manager.org)? It is not on the list, but might be compatible to some other driver. We already have an old LUDL control unit for the stage that is controlled by micromanager. Thanks
swick  (posted 2016-09-27 10:47:20.0)
This is a response from Sebastian at Thorlabs. Thank you for the inquiry. The 4-Channel LED-Drivers (DC4100 and DC4104), which are used to control the 4-Wavelength High-Power LED Source, are compatible to micromanager. I have contacted you directly with more detailed information how this can be done.
eddie.ross  (posted 2016-07-29 15:50:42.387)
Could you provide some information on how well collimated the beam is? Thanks
swick  (posted 2016-08-02 09:12:43.0)
This is a response from Sebastian at Thorlabs. Thank you very much for your inquiry. At the moment we unfortunately cannot provide information on divergence of the output beams emitted by LED4D231. I have contacted you directly to discuss the needs and expectations of your application.
saharv  (posted 2016-05-24 03:57:54.873)
The 4-Wavelength High-Power LED Source could be very useful for my project but it could been even better if it had white broad band LED in the available selection list. If there is any update in this parameter, I'll be happy to add broad white LED to the light source I'm planning to purchase for my lab. Thanks, Sahar
shallwig  (posted 2016-05-25 04:21:10.0)
This is a response from Stefan at Thorlabs. Thank you very much for your feedback. With our currently available 4 wavelength LED system from its design with built dichroic mirrors it is not possible to create a white broadband output spectrum. We will take your feedback into consideration for the development of next generation multi-color LED systems. At the moment we can offer the MBB1L3 broadband LED.
pain  (posted 2013-11-04 10:30:27.457)
could you provide with a reference for the electrical connectors ( 14points cylindrical) ? thanks
tschalk  (posted 2013-11-11 03:40:06.0)
This is a response from Thomas at Thorlabs. Thank you very much for your inquiry. The name of the connector is IEC 130-9 (http://www.binder-connector.com/en/products/924?onserie=1 ). I will contact you directly with more detailed information.
pain  (posted 2013-09-25 12:19:10.653)
I would like to know the output power at the exit of a 3 or 5 mm Liquid Light guide associated to the 470nm, 530,590,625nm leds. thanks
tschalk  (posted 2013-10-15 04:52:00.0)
This is a response from Thomas at Thorlabs. Thank you very much for your inquiry. This information is provided in the table on our web site: http://www.thorlabs.com/newgrouppage9.cfm?objectgroup_id=3836&pn=LED4B1#7320.
tschalk  (posted 2012-12-21 06:20:00.0)
This is a response from Thomas at Thorlabs. Thank you very much for your inquiry. Unfortunately we do not have this information but I will be very happy to simulate it for you. I will contact you with more detailed information. Best Regards, Thomas
mhawks  (posted 2012-12-19 13:29:54.733)
Do you have any specifications on how well-collimated the beam is?
tschalk  (posted 2012-12-19 10:26:00.0)
This is a response from Thomas at Thorlabs. Thank you very much for your inquiry. It is possible to integrate an excitation filter into the 4 Wavelength High-Power LED Source. This filter will influence all four wavelengths. I will contact you directly for more detailed information. Best Regards, Thomas
tschalk  (posted 2012-12-19 09:50:00.0)
This is a response from Thomas at Thorlabs. Thank you very much for your inquiry. Unfortunately we do not have a setup yet were it is possible to couple light from a 4-color LED source into a liquid light guide. However, you could use a lens tube, for example SM2L30, with an aspheric condenser lens, for example ACL5040-A. The lens tube fits into the SM2 threading on the 4-color LED source. To mount a liquid light guide you can use two adapters, SM2A6 and AD5LLG. It is a good idea to have a complete setup with an aligned lens. I will forward this idea to our development department so that we will be able to offer a part like this in the future. Best Regards, Thomas
heyderc  (posted 2012-12-18 15:20:11.607)
I would also like to know if it is possible to fit excitation filters into the LED source. Thanks.
heyderc  (posted 2012-12-18 17:31:48.753)
I would like to know if the 4-color LED source can be coupled to a liquid light guide. Thanks, Chris
tschalk  (posted 2012-11-14 06:29:00.0)
A response from Thomas at Thorlabs: Thank you for your inquiry! The lower power is caused through losses inside the housing. The divergence of the LED-Chips is very high and the beam is guided with mirrors to the condenser lens for collimation. Because of this setup a lot of optical energy gets lost. The lens of a single collimated LED is located directly in front of the LED-Chip and this causes almost no losses.
eozkan  (posted 2012-11-12 21:47:25.213)
Hello, Could you help me understand why power measurements on 4 wavelength high power led source are much lower single wavelength collimated led sources?(compare 470 for example: 25 mW on this product vs. >800 if purchased seperately) thanks,
jvigroux  (posted 2012-06-20 10:04:00.0)
A response from Julien at Thorlabs: Thank you for your inquiry! This should be in principle possible but will largely depend on the exact combination of wavelengths you need. I will contact you directly to see which possible combination would work best for you
dario.protti  (posted 2012-06-20 01:11:26.0)
would it be possible to use 3 LEDs in the visible range and one infrared (~850nm)? many thanks in advance
jvigroux  (posted 2012-01-26 07:37:00.0)
A response from Julien at Thorlabs: Thank you for your inquiry! The LEDs will yield about the same spectral irradiance as a HOB mercury lamp. The LED however will have wider spectral distribution than the individual mercury lamps such that their efficiency will also depend on the width of the fluorescent proteins you use. I will contact you directly to further discuss those points
ron.goldstein  (posted 2012-01-24 11:44:04.0)
I would like to use this light source for live imaging of cells with fluorescent proteins GFP/mCherry etc. I currently use a 100W HBO mercury lamp and exciter filters. How does the INTENSITY of the light from this LED source compare to that of at mercury lamp at 455/590/627? Thanks
jvigroux  (posted 2011-12-19 13:09:00.0)
a response form Julien at Thorlabs: Thank you for your feedback! the design of the LED4C LED source only allows the simultaneous use of four different wavelengths. Further, there is to our knowledge no high power LED available at 340nm. We should discuss more closely what the exact requirements for your application are as based on the exact output power required, there might be some other type of setup allowing to achieve the wavelength combination you need. Unfortunately, for now the use of the software within MetaMorph/MetaFluor is not yet implemented. The suggestion to emulate the Sutter filter wheel seems like a goop approach. Our software engineers are having a look into this and I should be able to post further information about the feasibility of such approach within the next 2-3 weeks.
gmcnamara  (posted 2011-12-16 19:03:14.0)
I would like to use a 4LED - or better yet 5LED - for Fura-2 Calcium ion ratio imaging, plus GFP, DsRed and Cy5/Alexa Fluor 647 (not necessarily at one time). I will need: ~340 nm LED (in addition to 385, 470, 530 and hopefully 627 LEDs). specific bandpass filtes to eliminate the tails of the LED spectra - especially so that I can have a clean separation of ~340 nm from ~385 nm light. I can select the appropriate filter sets for inside my microscope, once you/I/we figure out the LED bandpass filters. Probably a Fura-2 + Cy5 filter set and a DAPI/Green/Red triple pass set. I find your 4LED + microscope adapter product selection line-up on your web site confusing. I need more useful software integration than uManager. You never posted a follow-up to the 2009-11-24 posting about third party software. I am especially interested in MetaMorph/MetaFluor. If you do not want to work with vendors one by one, a suggstion: consider emulating a Sutter 10-2 filter wheel and shutter, with USB control (you can use the uManager Sutter interface to test the emulation).
bdada  (posted 2011-11-08 10:53:00.0)
Response from Buki at Thorlabs: Thank you for your interest in our 4 wavelength LED source. We will contact you for more information about your applications and the options for customization of the unit.
richard.norman  (posted 2011-11-07 18:25:14.0)
Interested in using it for a different application, but I'm having difficulty determining the output levels. May need different output optics. Can they be changed? Contact me and I'll explain the application.
jvigroux  (posted 2011-08-10 11:48:00.0)
A response from Julien at Thorlabs: Thank you for your feedback. As of now, we do not have dichroic mirrors that allow to cover the necessary spectrum for the combination you need (from 450nm to 850nm). This is the main reason why the maximum wavelengths for those four colors LEDs is about 670nm. Maybe an different arrangement using single LEDs could also work for your application. I will contact you directly to discuss this approach.
pbenzel  (posted 2011-08-09 11:53:30.0)
Can a LED4C1 be ordered with the following wavelengths 455, 530, 627, 850nm?
bdada  (posted 2011-04-26 12:14:00.0)
Response from Buki at Thorlabs: Thank you for your feedback. The DC4100 controller allows you to switch on all 4 LEDs at once. Please refer to page 11 of the DC4100 manual linked below to learn more about the multi selection mode: http://www.thorlabs.com/Thorcat/18300/18321-D02.pdf You can also access the manual and other technical documents for each product on our website. If you have any questions, please contact TechSupport@thorlabs.com.
michael.halter  (posted 2011-04-26 10:25:40.0)
Can the light from all four LEDs be output at the same time (such that I could filter all light in the microscope body)?
jjurado  (posted 2011-03-15 08:46:00.0)
Response from Javier at Thorlabs to Karl Farrow: I will contact you directly to discuss your application.
karl.farrow  (posted 2011-03-15 11:14:36.0)
Im very interested in purchasing this product but with a different set of mounted LEDs. Could you please contact me to discuss if this is possible. Thanks Karl Farrow
julien  (posted 2010-12-08 05:22:39.0)
A response from Julien at Thorlabs: Dear Shin-young, the LED4CX have an internal SM2 thread on which the microscope adapters LED4AX can be directly mounted. I will contact you directly to see exactly what the problem with your adapter is.
ryusy123  (posted 2010-12-07 07:06:28.0)
I purchased LED4C and olympus adapter but I cannot find the right way to mount this LED4C with the olympus adapter LED4A1. my microscope is olympus IX71. Please let me know how to mount Thank you. Shin-Young Ryu
egentzsch  (posted 2009-11-24 16:42:30.0)
A response from Erik at Thorlabs to lhall: This driver has its own software (Graphical User Interface) and software drivers. Currently it supports only the software µManager. I will check if it is possible to integrate it into third party software.
lhall  (posted 2009-11-20 08:48:06.0)
Hi again, Forgot to ask if this system will work with Metamorph, Slidebook or Olympus SIS software or other software. Please advise. Lance R. Hall Leeds
lhall  (posted 2009-11-20 08:44:57.0)
Has this been used for fluorescent application, most noteably for GFP and CFP. thanks, Lance R. Hall Senior Technical Sales Leeds Instruments, Inc. San Antonio, Texas Cell: (210) 421 4953
Light Emitting Diode (LED) Selection Guide
(Click
Representative
Photo to Enlarge;
Not to Scale)
WavelengthUnmounted
LEDs
Pigtailed LEDsLEDs in
SMT Packages
PCB-
Mounted LEDs
Heatsink-
Mounted LEDs
Collimated LEDs for MicroscopyaFiber-
Coupled LEDs
b
High-Power LEDs for MicrosocopyMulti-Wavelength
LED Source
Optionsc
LED Arrays
Single Color LEDs
250 nmLED250J
(1 mW Min)
---------
255 nmLED255W
(0.4 mW)
---------
LED255J
(1 mW Min)
260 nmLED260W
(1 mW)
---------
LED260J
(1 mW Min)
265 nm---M265D4
(38.4 mW Min)d
M265L5
(38.4 mW Min)d
-----
275 nmLED275W
(1.6 mW)
--M275D2
(45 mW Min)
M275L4
(45 mW Min)
-----
LED275J
(1 mW Min)
M275D3
(47.3 mW Min)
280 nmLED280W
(2.3 mW)
---M280L6
(78 mW Min)d
-M280F5
(0.5 mW Min)d
---
285 nmLED285W
(1.6 mW)
---------
LED285J
(1.3 mW)
290 nmLED290W
(1.6 mW)
---------
295 nmLED295W
(1.2 mW)
---------
300 nmLED300W
(1.2 mW)
--M300D3
(26 mW Min)
M300L4
(26 mW Min)
-M300F2
(320 µW)
---
308 nm---M310D1
(38.5 mW Min)d
M310L1
(38.5 mW Min)d
-M310F1
(0.51 mW)d
---
310 nmLED310W
(1.5 mW)
---------
325 nmLED325W2
(1.7 mW)
--M325D3
(25 mW Min)
M325L5
(25 mW Min)
-M325F4
(350 µW)
---
340 nmLED340W
(1.7 mW)
--M340D4
(45.5 mW Min)d
M340L5
(45.5 mW Min)d
-M340F4
(0.75 mW)d
---
LED341W
(0.33 mW)
365 nm---M365D2
(1150 mW Min)
M365L3
(880 mW Min)
M365L2-Cx
(120 mW)g
M365FP1
(15.5 mW)
SOLIS-365C
(3.0 W)f
Chrolis
(1130 mW)
-
M365LP1
(1350 mW Min)
M365LP1-Cx
(350 mW)e
4-Wavelength
Source
(85 mW)
375 nmLED375L
(1 mW)
--M375D4
(1270 mW Min)
M375L4
(1270 mW Min)
-M375F2
(4.23 mW)
---
LED370E
(2.5 mW)
385 nmLED385L
(5 mW)
--M385D1
(270 mW Min)
M385L2
(270 mW Min)
M385L2-Cx
(90 mW)e
M385F1
(10.7 mW)
SOLIS-385C
(5.8 W)f
Chrolis
(1250 mW)
-
M385L3
(1240 mW Min)
M385L3-Cx
(450 mW)e
M385D2
(1650 mW Min)
M385LP1
(1650 mW Min)
M385LP1-Cx
(520 mW)e
M385FP1
(23.2 mW)
4-Wavelength
Source
(95 mW)
395 nmLED395L
(6 mW)
--M395D3
(400 mW Min)
M395L4
(400 mW Min)
-M395F3
(6.8 mW)
---
M395D4
(1420 mW Min)
M395L5
(1130 mW Min)
M395FP1
(29.8 mW)
M395LP1
(1420 mW Min)
WavelengthUnmounted
LEDs
Pigtailed LEDsLEDs in
SMT Packages
PCB-
Mounted LEDs
Heatsink-
Mounted LEDs
Collimated LEDs
for Microscopy
a
Fiber-
Coupled LEDs
b
High-Power LEDs
for Microsocopy
Multi-Wavelength
LED Source
Optionsc
LED Arrays
Single Color LEDs
405 nmLED405L
(6 mW)
--M405D2
(1500 mW Min)
M405L4
(1000 mW Min)
M405L4-Cx
(510 mW)g
M405F1
(3.7 mW)
SOLIS-405C
(3.9 W)f
Chrolis
(900 mW)
-
4-Wavelength
Source

(290 mW)
LED405E
(10 mW)
M405LP1
(1200 mW Min)
M405LP1-Cx
(450 mW)e
M405FP1
(24.3 mW)
415 nm---M415D2
(1640 mW Min)
M415L4
(1310 mW Min)
-M415F3
(21.3 mW)
SOLIS-415C
(5.8 W)f
--
M415LP1
(1640 mW Min)
420 nm--------Chrolis
(710 mW)
-
4-Wavelength
Source
(95 mW)
430 nmLED430L
(8 mW)
--M430D3
(529.2 mW Min)d
M430L5
(529.2 mW Min)d
-M430F1
(7.5 mW)d
---
445 nm-------SOLIS-445C
(5.4 W)f
--
450 nmLED450L
(7 mW)
-LEDS450
(250 mW)
M450D4
(2118.1 mW)d
M450LP2 (2118.1 mW)d-----
455 nm---M455D3
(1150 mW Min)
M455L4
(1150 mW Min)
M455L3-Cx
(400 mW)h
M455F3
(24.5 mW)
-4-Wavelength
Source
(310 mW)
-
M455L4-Cx
(490 mW)e
465 nmLED465E
(20 mW)
---------
470 nmLED470L
(170 mW)
EP470S04
(18 mW Min)
-M470D4
(809 mW Min)d
M470L5
(809 mW Min)d
M470L5-Cx
(402 mW)e
M470F3
(21.8 mW)
SOLIS-470C
(3.0 W)f
4-Wavelength
Source
(250 mW)
LIU470A
(253 mW)
EP470S10
(100 mW Min)
475 nm--------Chrolis
(630 mW)
-
490 nmLED490L
(3 mW)
--M490D3
(205 mW Min)
M490L4
(205 mW Min)
-M490F3
(3.1 mW)
-Chrolis
(120 mW)
-
4-Wavelength
Source
(50 mW)
505 nmLED505L
(4 mW)
--M505D3
(400 mW Min)
M505L4
(400 mW Min)
M505L3-Cx
(180 mW)j
M505F3
(11.7 mW)
SOLIS-505C
(1.0 W)f
4-Wavelength
Source
(170 mW)
-
M505L4-Cx
(170 mW)e
525 nmLED525E
(2.6 mW Max)
------SOLIS-525C
(2.4 W)f
Chrolis
(180 mW)
LIU525A
(111 mW)
LED525L
(4 mW)
LED528EHP
(7 mW)
530 nm---M530D3
(370 mW Min)
M530L4
(370 mW Min)
M530L4-Cx
(160 mW)e
M530F2
(9.6 mW)
-4-Wavelength
Source
(100 mW)
-
545 nmLED545L
(2.4 mW CW, 8.7 mW Pulsed)
---------
554 nm---MINTD3
(650 mW Min)
MINTL5
(650 mW Min)
-MINTF4
(28 mW)
---
562 nmLED560L
(0.15 mW)d
---------
565 nm---M565D2
(880 mW Min)
M565L3
(880 mW Min)
-M565F3
(13.5 mW)
SOLIS-565C
(3.2 W)f
Chrolis
(350 mW)
-
4-Wavelength
Source
(106 mW)
570 nmLED570L
(0.3 mW)
---------
590 nmLED590L
(2 mW)
EP590S04
(3.5 mW Min)
-M590D3
(230 mW Min)
M590L4
(230 mW Min)
M590L3-Cx
(60 mW)e
M590F3
(4.6 mW)
SOLIS-590C
(350 mW)f
Chrolis
(140 mW)
LIU590A
(109 mW)
LED591E
(2 mW)
EP590S10
(18 mW Min)
M590L4-Cx
(100 mW)e
4-Wavelength
Source
(65 mW)
595 nm---M595D3
(820 mW Min)
M595L4
(820 mW Min)
-M595F2
(11.5 mW)
SOLIS-595C
(700 mW)f
--
WavelengthUnmounted
LEDs
Pigtailed LEDsLEDs in
SMT Packages
PCB-
Mounted LEDs
Heatsink-
Mounted LEDs
Collimated LEDs
for Microscopy
a
Fiber-
Coupled LEDs
b
High-Power LEDs
for Microsocopy
Multi-Wavelength
LED Source
Optionsc
LED Arrays
Single Color LEDs
600 nmLED600L
(3 mW)
---------
610 nmLED610L
(8 mW)
---------
617 nm---M617D2
(600 mW Min)
M617L3
(600 mW Min)
M617L3-Cx
(230 mW)e
M617F2
(13.2 mW)
SOLIS-617C
(1.5 mW)f
4-Wavelength
Source
(210 mW)
-
M617L4-Cx
(280 mW)e
620 nm-------SOLIS-620D
(3.47 W)f
--
625 nmLED625L
(12 mW)
--M625D3
(700 mW Min)
M625L4
(700 mW Min)
M625L3-Cx
(270 mW)e
M625F1
(17.5 mW)
-Chrolis
(490 mW)
-
M625L4-Cx
(490 mW)e
4-Wavelength
Source
(240 mW)
630 nmLED630L
(16 mW)
--------LIU630A
(208 mW)
635 nmLED631E
(4 mW)
---------
LED635L
(170 mW)
639 nmLED630E
(7.2 mW)
---------
645 nmLED645L
(16 mW)
---------
660 nmLED660L
(13 mW)
--M660D2
(940 mW Min)
M660L4
(940 mW Min)
M660L4-Cx
(400 mW)e
M660FP1
(15.5 mW)
SOLIS-660C
(2.0 W)f
4-Wavelength
Source
(210 mW)
-
670 nmLED670L
(12 mW)
---------
680 nmLED680L
(8 mW)
--M680D2
(180 mW Min)
M680L4
(180 mW Min)
-M680F3
(2.7 mW)
---
700 nm-EP700S04
(5 mW Min)
-M700D2
(80 mW Min)
M700L4
(80 mW Min)
-M700F3
(1.7 mW)
---
EP700S10
(30 mW Min)
730 nm---M730D3
(540 mW Min)
M730L5
(540 mW Min)
-----
740 nm------M740F2
(6.0 mW)
SOLIS-740C
(2.0 W)f
--
750 nmLED750L
(18 mW)
---------
760 nmLED760L
(24 mW)
---------
770 nmLED770L
(22 mW)
---------
780 nmLED780E
(18 mW)
--M780D2
(200 mW Min)
M780L3
(200 mW Min)
M780L3-Cx
(130 mW)e
M780F2
(7.5 mW)
-Chrolis
(40 mW)
LIU780A
(315 mW)
LED780L
(22 mW)
M780D3
(800 mW Min)
M780LP1
(800 mW Min)
800 nmLED800L
(20 mW)
---------
810 nmLED810L
(22 mW)
EP810S04
(16 mW Min)
-M810D2
(325 mW Min)
M810L3
(325 mW Min)
M810L3-Cx
(210 mW)e
M810F2
(6.5 mW)
---
EP810S10
(90 mW Min)
M810L4
(363 mW Min)
830 nmLED830L
(22 mW)
---------
840 nmLED840L
(22 mW)
---------
850 nmLED851L
(13 mW)
--M850D2
(900 mW Min)
M850L3
(900 mW Min)
M850L3-Cx
(330 mW)e
M850F3
(8.6 mW Min)d
SOLIS-850C
(2.7 W)f
-LIU850A
(322 mW)
M850D3
(1400 mW)
M850LP1
(1400 mW Min)
870 nmLED870E
(22 mW)
---------
LED870L
(24 mW)
880 nm---M880D2
(300 mW Min)
M880L3
(300 mW Min)
-M880F2
(3.4 mW)
---
890 nmLED890L
(12 mW)
---------
910 nmLED910L
(10 mW)
---------
LED910E
(12 mW)
930 nmLED930L
(15 mW)
--------
940 nmLED940E
(18 mW)
--M940D2
(800 mW Min)
M940L3
(800 mW Min)
M940L3-Cx
(320 mW)e
M940F3
(14.2 mW)
SOLIS-940C
(2.5 W)f
--
970 nmLED970L
(5 mW)
--M970D3
(600 mW Min)
M970L4
(600 mW Min)
-M970F3
(8.1 mW)
---
WavelengthUnmounted
LEDs
Pigtailed LEDsLEDs in
SMT Packages
PCB-
Mounted LEDs
Heatsink-
Mounted LEDs
Collimated LEDs
for Microscopy
a
Fiber-
Coupled LEDs
b
High-Power LEDs
for Microsocopy
Multi-Wavelength
LED Source
Optionsc
LED Arrays
Single Color LEDs
1050 nmLED1050E
(2.5 mW)
--M1050D1
(50 mW Min)
M1050L2
(50 mW Min)
-----
LED1050L
(4 mW)
M1050D3
(160 mW Min)
M1050L4
(160 mW Min)
M1050F3
(3 mW)
LED1050L2
(8 mW)d
---
1070 nmLED1070L
(4 mW)
---------
LED1070E
(7.5 mW)
1085 nmLED1085L
(5 mW)
---------
1100 nm---M1100D1
(168 mW Min)d
M1100L1
(168 mW Min)d
-M1100F1
(5.4 mW)d
---
1200 nmLED1200E
(2.5 mW)
--M1200D2
(30 mW Min)
M1200L3
(30 mW Min)
-----
LED1200L
(5 mW)
1300 nmLED1300E
(2 mW)
--M1300D2
(25 mW Min)
M1300L3
(25 mW Min)
-M1300F1
(2.31 mW)d
---
LED1300L
(3.5 mW)
M1300D3
(122.8 mW Min)d
M1300L4
(122.8 mW Min)d
1450 nmLED1450E
(2 mW)
---------
LED1450L
(5 mW)
1550 nmLED1550E
(2 mW)
--M1550D2
(31 mW Min)
M1550L3
(31 mW Min)
-----
LED1550L
(4 mW)
1600 nmLED1600L
(2 mW)
---------
1650 nmLED1600P
(1.2 mW)
--M1650D2
(13 mW Min)
M1650L4
(13 mW Min)
-----
1750 nmLED1700P
(1.2 mW
Quasi-CW,
30 mW Pulsed)
---------
1850 nmLED1800P
(0.9 mW
Quasi-CW,
20 mW Pulsed)
---------
1950 nmLED1900P
(1.0 mW
Quasi-CW,
25 mW Pulsed)
---------
2050 nmLED2050P
(1.1 mW
Quasi-CW,
28 mW Pulsed)
---------
2350 nmLED2350P
(0.8 mW
Quasi-CW,
16 mW Pulsed)
---------
2700 nmLED2700W
(0.15 mW
Quasi-CW,
1.0 mW
Pulsed)
---------
2800 nmLED2800W
(0.3 mW
Quasi-CW,
2.0 mW
Pulsed)
---------
3400 nmLED3400W
(0.3 mW
Quasi-CW,
2.0 mW
Pulsed)
--M3400D1
(2.2 mW Min)d
M3400L1
(2.2 mW Min)d
-----
3800 nmLED3800W
(0.18 mW
Quasi-CW,
1.5 mW
Pulsed)
---------
4200 nmLED4300P
(0.03 mW
Quasi-CW,
0.2 mW Pulsed)
---------
4300 nmLED4300W
(0.18 mW
Quasi-CW,
1.5 mW
Pulsed)
--M4300D1
(1.1 mW Min)d
M4300L1
(1.1 mW Min)d
-----
4500 nmLED4600P
(0.006 mW
Quasi-CW,
0.12 mW Pulsed)
---------
WavelengthUnmounted
LEDs
Pigtailed LEDsLEDs in
SMT Packages
PCB-
Mounted LEDs
Heatsink-
Mounted LEDs
Collimated LEDs
for Microscopy
a
Fiber-
Coupled LEDs
b
High-Power LEDs
for Microsocopy
Multi-Wavelength
LED Source
Optionsc
LED Arrays
Multi-Color, Broadband, and White LEDs
455 nm (12.5%i) and 640 nm---MPRP1D2
(275 mW Min)
MPRP1L4
(275 mW Min)
-----
572 nm
and 625 nm
LEDGR
(0.09 mW
and 0.19 mW)
---------
588 nm and 617 nmLEDRY
(0.09 mW
and 0.19 mW)
---------
467.5 nm,
525 nm,
and 627.5 nm
LEDRGBE
(5.8 mW,
6.2 mW,
and 3.1 mW)
---------
430 - 660 nm
(White)
LEDWE-15
(13 mW)
---------
LEDW7E
(15.0 mW)
LEDW25E
(15.0 mW)
6500 K
(Cold White)
---MCWHD5
(930 mW Min)
MCWHL7
(930 mW Min)
--SOLIS-1D
(5.8 W)f
--
MCWHD6
(942 mW Min)d
MCWHLP2
(942 mW Min)d
MCWHD7
(2064.8 mW Min)d
MCWHLP3
(2064.8 mW Min)d
6200 K
(Cold White)
------MCWHF2
(27.0 mW)
---
5000 K
(Cold White)
--LEDSW50
(110 mW)
-------
4600 - 9000 K
(Cold White)
---------LIUCWHA
(250 mW)
4000 K
(Warm White)
--LEDSW40
(115 mW)
---MWWHF2
(23.1 mW)
---
3000 K
(Warm White)
--LEDSW30
(100 mW)
MWWHD4
(1713 mW Min)d
MWWHL4
(570 mW Min)
--SOLIS-2C
(3.2 W)f
--
MWWHLP2
(1713 mW Min)d
5700 K
(Day Light White)
-------SOLIS-3C
(3.5 W)
--
470 - 850 nm
(Broadband)
---MBB1D1
(70 mW Min)
MBB1L3
(70 mW Min)
-MBB1F1
(1.2 mW)
---
770 nm, 860 nm, & 940 nm
(Broadband)
---MBB2D1
(740 mW Min)
MBB2L1
(650 mW Min)
-----
MBB2LP1
(740 mW Min)
  • これらのコリメートLEDは、以下の顕微鏡の標準ポートならびに落射照明用ポートに取り付けることができます:Olympus BX/IX(型番末尾:-C1)、Leica DMI(型番末尾:-C2)、Zeiss Axioskop(型番末尾:-C4)、Nikon Eclipse(バヨネットマウント、型番末尾:-C5)
  • コア径Ø400 µm、NA 0.39のマルチモードファイバを使用した際の典型出力
  • 当社の多波長LED光源は、対応可能な波長のLEDを組み合わせて使用できます。
  • 25℃で測定
  • Leica DMI用コリメーターパッケージ(型番末尾:-C2)に使用したLEDの典型値
  • これらのLEDの最大電流時におけるコリメート出力の最小出力 コリメート用レンズは各LEDに取付け済み
  • Olympus BX/IX用コリメーターパッケージ(型番末尾:-C1)に使用したLEDの典型値
  • Nikon Eclipse用コリメーターパッケージ(型番末尾:-C5)に使用したLEDの典型値
  • 400 nm~525 nmのスペクトルの青い領域で放射されるLEDの強度(%)
  • Zeiss Axioskop用コリメーターパッケージ(型番末尾:-C4)に使用したLEDの典型値

4波長LED照明

下記の波長構成ツールで4つの波長を選択いただくと、該当する製品の型番、資料、定価(税抜)をご確認いただけます。定価は選択いただく波長の組合せにかかわらず同一ですが、型番は異なりますのでご注意ください。

Please build your custom system below:
LED Spectra
Choose your LEDs:
LED 1 nm
LED 2
nm
LED 3
nm
LED 4
nm

SM2外ネジ付き顕微鏡用アダプタ


Olympus製顕微鏡に取り付けられる4波長照明

SM2ネジ付き取付けアダプタをお使いいただくと、4波長LED照明をOlympus、Leica、Nikon、またはZeiss製顕微鏡に取り付けることができます。右の動画では、この照明をOlympus製顕微鏡に取り付ける方法をご覧いただけます。

Item #LED4A1LED4A2LED4A4LED4A5
(Click Photo to Enlarge)LED4A1LED4A2LED4A4LED4A5
Compatible MicroscopeOlympusLeicaZeissNikon Eclipse
+1 数量 資料 型番 - ユニバーサル規格 定価(税抜) 出荷予定日
LED4A1 Support Documentation
LED4A1Olympus製BX41、IX71、IX73顕微鏡透過照明ポート用アダプタ、SM2外ネジ付き、銀色アルマイト加工
¥9,121
7-10 Days
LED4A2 Support Documentation
LED4A2Leica製DMI顕微鏡用ランプハウスポートアダプタ、SM2外ネジ付き、銀色アルマイト加工
¥9,121
Lead Time
LED4A4 Support Documentation
LED4A4Zeiss AxioskopおよびExaminer顕微鏡用ランプハウスポートアダプタ、SM2外ネジ付き、銀色アルマイト加工
¥9,121
7-10 Days
LED4A5 Support Documentation
LED4A5Nikon製Eclipse顕微鏡落射照明モジュール用バヨネットマウントアダプタ、SM2外ネジ付き、銀色アルマイト加工
¥15,427
7-10 Days

液体ライトガイド用アダプタ

Output Power of 4-Wavelength LED Source with Liquid Light Guide Attached
LED Nominal
Wavelength
Power through LLGLED Nominal
Wavelength
Power through LLG
Ø3 mm Core,
6' (1.8 m) Long
Ø5 mm Core,
4' (1.2 m) Long
Ø3 mm Core,
6' (1.8 m) Long
Ø5 mm Core,
4' (1.2 m) Long
365 nm35 mW110 mW505 nm70 mW150 mW
385 nm65 mW120 mW530 nm15 mW55 mW
405 nm110 mW330 mW565 nm57 mW93 mW
420 nm15 mW63 mW590 nm20 mW45 mW
455 nm105 mW250 mW617 nm80 mW150 mW
470 nm105 mW275 mW625 nm100 mW200 mW
490 nm10 mW30 mW660 nm100 mW190 mW

液体ライトガイド用アダプタLED4B1には非球面コンデンサーレンズ(ACL2520-A)が付いており、この非球面レンズが4波長LED照明からの光をLLG-SM1アダプタに保持された液体ライトガイド(LLG)に集光します(LLG-SM1アダプタは付属しておりません)。アダプタLED4B1のSM1内ネジ付きの出力ポートには、コア径Ø3 mmのLLG用のSM1アダプタAD3LLGならびにコア径Ø5 mmの同アダプタAD5LLGを接続できます。当社の液体ライトガイドのより詳しい情報は、こちらでご紹介しています。

液体ライトガイド用アダプタLED4B1は、4波長照明のSM2ネジ付きのコリメータ出力ポートとボルトパターンが同じです。設置するには、4本のM2.5ネジを抜いて照明の出力ポートを外し、そのネジを使ってアダプタLED4B1を取り付けてください。その後、ネジを締め、LLGを取り付けてください。具体的な設置方法については「LLGの取付け」のタブをご覧ください。

+1 数量 資料 型番 - ユニバーサル規格 定価(税抜) 出荷予定日
LED4B1 Support Documentation
LED4B1Customer Inspired! 液体ライトガイド用アダプタ、4波長LED照明用
¥19,611
Today
AD3LLG Support Documentation
AD3LLGCustomer Inspired! SM1ネジ変換アダプタ、Ø3 mm液体ライトガイド用
¥4,651
Today
AD5LLG Support Documentation
AD5LLGCustomer Inspired! SM1ネジ変換アダプタ、Ø5 mm液体ライトガイド用
¥4,651
Today

高性能4チャンネルLEDドライバ

  • 4チャンネルを個別に精密調整可能
  • 変調周波数: 0~100 kHz(正弦波)
  • LED電流: 1 A (最大)
  • 駆動電圧: 5 V (最大)

4チャンネルLEDドライバ DC4100シリーズは、LED4Dシリーズ光源を便利に制御できるよう設計されています。詳細は、DC4100シリーズの製品ページをご覧ください。

+1 数量 資料 型番 - ユニバーサル規格 定価(税抜) 出荷予定日
DC4100 Support Documentation
DC41004チャンネルLEDドライバ、1変調入力、1 A、5 V
¥380,523
7-10 Days
DC4104 Support Documentation
DC4104Customer Inspired! 4チャンネルLEDドライバ、4変調入力、1 A、5 V
¥418,734
Today
Last Edited: Jul 30, 2013 Author: Tina Aragona