
Multiwave Photonics
Founded Year
2003Stage
Series B | AliveTotal Raised
$7.72MLast Raised
$7.72M | 15 yrs agoAbout Multiwave Photonics
Multiwave offers pulsed fiber lasers that allow the customer to control its key operating parameters in ways. Multiwave also offers other optical sources based on fiber-optic technologies, as well as product design, product development and engineering services aimed at developing and selling cost-effective and reliable products and solutions.
Multiwave Photonics Patents
Multiwave Photonics has filed 1 patent.

Application Date | Grant Date | Title | Related Topics | Status |
---|---|---|---|---|
6/11/2009 | 1/3/2012 | Fiber optics, Laser science, Optical devices, Ophthalmology, Optical fiber | Grant |
Application Date | 6/11/2009 |
---|---|
Grant Date | 1/3/2012 |
Title | |
Related Topics | Fiber optics, Laser science, Optical devices, Ophthalmology, Optical fiber |
Status | Grant |
Multiwave Photonics Frequently Asked Questions (FAQ)
When was Multiwave Photonics founded?
Multiwave Photonics was founded in 2003.
Where is Multiwave Photonics's headquarters?
Multiwave Photonics's headquarters is located at Rua Eng. Frederico Ulrich, 2650, Maia.
What is Multiwave Photonics's latest funding round?
Multiwave Photonics's latest funding round is Series B.
How much did Multiwave Photonics raise?
Multiwave Photonics raised a total of $7.72M.
Who are the investors of Multiwave Photonics?
Investors of Multiwave Photonics include GP BullHound Sidecar, Bullnet Gestion and Armilar Venture Partners.
Who are Multiwave Photonics's competitors?
Competitors of Multiwave Photonics include Lawrenceville Plasma Physics and 4 more.
Compare Multiwave Photonics to Competitors
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Calabazas Creek Research, Inc. is a Palo Alto, CA based company that has received a grant(s) from the Department of Energy's SBIR/STTR program. The abstract(s) for these grant award(s) are provided as well since they provide insights into Calabazas Creek Research, Inc.'s business and areas of expertise. This project will focus on increasing the efficiency of the analysis and design of components used in over-moded transmission lines. Over-moded transmission lines are used for a variety of applications for low loss transmission of microwave and millimeter waves. Efficient, high power, radio frequency sources are required for many planned and proposed accelerator programs. This project will develop a new radio frequency source that would be more efficient, more compact, and less costly then existing alternatives. This project will develop a 10 MW, 1.3 GHz annular beam klystron. The advanced design of the ABK is offers system costs that are significantly lower than those possible with conventional klystrons. The ABK will be useful for research and medical accelerators, and national defense and commercial applications. Successful development of a high power multiple beam klystron would provide an RF source for powering several accelerator systems desired at frequencies around 200 MHz. The proposed source would find applications in the United States, Europe, and Asia. This project will develop an advanced simulation code for photoinjectors that will help improve high-energy accelerator light-source performance benefiting applied research in biology, materials science and defense/security. This project will allow analysis of electrical breakdown on dielectric surface that increases the cost and reduce reliability of high power devices for high energy physics, defense, medical, and industrial applications. Successful development will allow design of more cost effective high power devices with increased reliability. This project will develop a new design tools for inductive output tubes. This will provide higher efficiency RF sources for driving high energy accelerators. High power waterload are necessary to meet the U.S. obligation to the ITER program for fusion energy research. This project will satisfy the ITER requirement and provide a waterload for other fusion facilities around the world. This project will investigate fundamental mode and higher order mode (HOM) IOTs for potential accelerator applications. Successful development of multiple beam inductive output tubes will demonstrate a new, high efficiency source for many high power RF applications. The device is simpler, more efficient, and less expensive then current devices. This program will develop new power coupler technology for the ILC. The technology developed will significantly advance the state-of-the-art in coupler design and be applicable to many world-wide accelerator projects. A fundamental mode (FM) multiple beam (MB) inductive output tube (IOT) is a candidate RF source to provide this power. The FM MB IOT offers compactness and improved efficiency. This program will generate designs for all major tube components. Successful development of multiple beam inductive output tubes will demonstrate a new, high efficiency source for many high power RF applications.

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