This is one of those “how to” videos that goes so much deeper than you think. Learn the skills and tactics of FPGV (Fiber Photonic Via) to create the best possible fiber optic cable solution.
FPGV Fiber Photonic Via is a patented fiber optic cable technology that uses lasers to create a fiber optic cable. The Laser then uses a laser diode to create the fiber optic cable that will transmit light signals over fiber optic cables.
This video goes into much more detail about the laser diode and fiber optic cable technology than I ever would have thought possible. It also explains how to make your own fiber optic cable with FPGV fiber optic via and how to use it to create the best possible fiber optic cable solution.
All I can say is thank you for the video. It really is a step in the right direction, and it demonstrates how easy fiber optic cables are to make. In a previous video I mentioned how I was able to make fiber optic cables at home with a breadboard approach and then use a laser diode to create them. I think this video explains how to do it better than I ever could.
If you want to make your own fiber optic cable, you need some fiber optic connectors and a laser diode. Most fiber optic connectors use a 1/4″ male connector for the fiber and a 1/4″ female connector for the fiber optic cable. The laser diode is a laser diode that uses a 1/2-microsecond pulse.
Basically, what you need is a laser diode that’s 12-microseconds long. You can buy this laser diode on eBay, but it’s not exactly cheap. The best way to make the laser diode is to make a breadboard out of a laser diode, a breadboard lead, and a breadboard connector. To make the breadboard lead, cut out a round that’s the thickness of a bread board.
What you’ll find is that you have two different types of laser diodes that are used in fiber optic cables. One type of laser diode is used for transmitting light, and the other type of laser diode is used for receiving light. Both are sold in various packages. You’ll find that these two different types of laser diodes come in packages that differ by the diameter of laser diode.
The large diameter laser diode is used to transmit the light, and the small diameter laser diode is used to receive and amplify the light. The large diameter laser diodes use a much longer path to transmit and a shorter path to receive the light. This leads to the smaller diameter laser diodes having higher transmission and lower reception efficiency.
The larger diameter laser diode is used to transmit the light, and the smaller diameter laser diode is used to receive and amplify the light. We chose the smaller diameter laser diodes because they are significantly cheaper than the larger diameter ones.