Category Archives: Fiber Optic Transport

Fiber Optic Video Transmission User’s Guide – Beginner to Expert in 20 Pages

Learn About Fiber Optic Video Transmission from the Expert

Jim Jachetta has compiled everything there is to know about Fiber Optics into 20 pages.

fiber optic video transmission guide

Whether you are a greenhorn or a professional, this will teach or refresh you on the topic of Fiber Optic Video Transmission. This guide is perfect at any level. First, we cover the basics. Then, we work up to the bleeding edge with 4K fiber optic video transmission. This guide is packed with practical examples. It provides the knowledge you need to become an expert quickly. Fiber Optic Video Transmission is regarded as low in latency and highly reliable. You may be exceedingly aware that Fiber Optics have trumped the speed of copper cable. You may also be aware that it provides unprecedented reliability that typical wireless setups cannot. Yet, it’s likely that you could use a refresher on the topic. The industry is moving fast. The applications of fiber optic video transmission are changing. It’s up to you to stay on top of it all. This user’s guide is the way to do that. We cover modern applications, end-to-end design, multiplexing, routing switchers, and the works!

Benefits of Fiber-Optic Video Transmission:

  • Longer Distances
  • Multiple Signals
  • Size
  • Weight
  • Noise Immunity
  • Ease of Installation
  • Connector Adaptability
  • Ease of Splicing
  • Low-Latency
  • Reliability
From time to time in my user’s guide, I may also show you some interesting fiber optic products you can take a look at such as these two below.
fiber optic video fiber optic video transmission
FVT/FVR-5400-3G, VidOptic 4 Channel 
3G HDSDI Fiber Optic Transport Card
with 4×4 Matrix for openGear
VidOptic Camera Back 4K & HD SDI 
Fiber Optic System
Posted in Educational Guides, Fiber Optic Medium, Fiber Optic Transport, Introduction to Fiber Optics, News, Optical Windows and Spectrum, Snells Law, Types of Fiber-optic Material, Users Guide to Fiber Optic Video Transmission | Tagged , , , , | 2 Comments

VidOvation Expands VidOptic Fiber Optic Transmission Product Family

Price–performance leadership designed for critical applications requiring high quality video performance and reliability across SD/HD-SDI, broadband, and RF optical networks

Irvine, California, January 7, 2014 – VidOvation, a leading technology provider of Fiber Optic Linksvideo and data communication systems to the broadcast television, sports, corporate audio-visual, and government markets, announced today that they are expanding their VidOptic product line of fiber optic transport systems specifically designed for critical applications requiring high quality video performance and reliability with price-performance leadership. The new product families include:

  1. USB-DVI Computer Graphics Transport
    (http://vidovation.com/fvt-fvr-2100-usb-dvi-single-link-dual-link-rgb-audio-data-usb-over-1-fiber)
    The VidOptic FVT/FVR-2100-A-D-USB-DVI is designed for optical KVM extension to transport computer graphics while extending computer control via USB and serial data transport. The system supports high–quality HDTV formats from 480P up to and including 1080P with full clarity over one fiber and the transport of non-RGB video formats such as YUV, YCrCb or YPrPb, RGB–HV, DVI–D and DVI-DL through a DVI–I interface… Continue reading
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User’s Guide to Fiber Optic Video Transmission – Types of Fiber-optic Material – Part 4

There are two distinct parts of a fiber optic cable—the optical fiber that carries the signal and the protective covering that keeps the fiber safe from environmental and mechanical damage. This section deals specifically with the optical fiber.

An optical fiber has two concentric layers called core and cladding. The core (inner part) is the light carrying part. The surrounding cladding provides the difference in refractive index that allows total internal reflection of light through the core. The index of refraction of the cladding is less than 1% lower than that of the core. Typical values, for example, are a core index of 1.47 and cladding index of 1.46. Fiber manufacturers must carefully control this difference to obtain the desired fiber characteristics.

Fibers have an additional coating around the cladding. This coating, which is usually one or more layers of polymer, protects the core and cladding from shocks that might affect their optical or physical properties. The coating has no optical properties affecting the propagation of light within the fiber. This coating is just a shock absorber.

FIGURE 6.10-4 Total internal reflection in an optical fiber. Rays of light incident on the core/cladding boundary at greater than the critical angle, determined by the quotient n1/n2, propagate down the fiber’s core at a velocity determined by that fiber’s value. One ray is shown to keep the diagram simple. (From AMP, Inc., copyright illustration, used with permission.)

Figure 6.10-4 shows the light traveling through a fiber. Light injected into the fiber and striking the core-to-cladding interface at a critical angle reflects back into the core. Since the angles of incident and reflection are equal, the light will again be reflected. The light will continue as expected down the length of the fiber.

Light, however, striking the interface at less than the critical angle passes into the cladding, where it is lost over distance. The cladding is usually inefficient as a light carrier, and light in the cladding becomes attenuated fairly rapidly. The propagation of light is governed by the indices of the core and cladding and by Snell’s Law.

Such total internal reflection forms the basis of light propagation through a simple optical fiber. This analysis considers only meridional rays, the rays that pass through the fiber center axis each time they are reflected. Other rays, called skew rays, travel down the fiber without passing through the axis. The path of the skew ray is typically helical, wrapping around and around the center axis. To simply analyze, skewer rays are ignored in most fiber-optics analysis.

FIGURE 6.10-5 Light ray acceptance cone geometry. The acceptance cone is an imaginary right angle cone extending outward coaxially from the fiber’s core. It is a measure of the light-gathering capability of a fiber. Its ray acceptance angle, called the numerical aperture (NA) of the fiber, is uniquely determined by the refractive indices of that fiber’s core and clad- ding. (From AMP, Inc., copyright illustration, used with permission.)

A cone known as the acceptance cone, shown in Figure 6.10-5, defines which light will be accepted and propagated by a total internal reflection. Light that enters the core from within this acceptance cone refracts down the fiber. Light outside the cone will not strike  the  core-to-cladding  interface  at  the  proper angle that allows total internal reflection. This light will not propagate.

The specific characteristics of light propagation through fiber depend on many factors. The factors include the size and composition of the fiber as well as the light source injected into the fiber. An understanding of the interplay between these properties will clarify many aspects of fiber optics.

Fiber itself has a very small diameter. Table 6.10-3 provides the core and cladding diameters of four commonly used fibers.

TABLE 6.10-3 Core and Cladding Diameters of Four Commonly Used Fibers

To realize how small these fibers are, note that human hair has a diameter of about 100 μ. Fiber sizes are usually expressed by first giving the core size, followed by the cladding size. Thus, 50/125 means a core diameter of 50 microns (μm) and a cladding diameter of 125 microns (μm).

Optical fibers are classified in two ways. One way is by the material makeup:

  • Glass fiber: Glass fibers have a glass core and glass cladding. They are the most widely used type of fiber. The glass used in an optical fiber is an ultra pure and transparent silicon dioxide or fused quartz. If ocean water was as clear as fiber, one could see to the bottom of the Marianas Trench in the Pacific Ocean, a depth of 36,000 feet. Impurities are purposely added to the pure class to achieve the desired index of refraction. The elements germanium and phosphorus are added to increase the refractive index of the glass. Boron or fluorine is used to decrease the index. There are other impurities that are not removed when the class is purified. These additional impurities also affect the fiber properties by increasing attenuation from scattering or by the absorbing light.
  • Plastic-clad silica (PCS): PCS fibers have a glass core and plastic cladding. The performance of PCS fiber is limited compared to a fiber made of all glass.
  • Plastic: Plastic fibers have a plastic core and plastic cladding. Plastic fibers are limited by high optical loss and low bandwidth. The very low cost and ease of use make them attractive for applications where low bandwidth or high losses are acceptable. Plastic and PCS fibers do not have the buffer coating surrounding the cladding.

The second way to classify fibers is by the refractive index of the core and the modes that the fiber propagates. Fiber can be categorized into three general types;  Figure  6.10-6  shows  the  three  general  fiber types and their basic characteristics.

Figure 6.10-6 shows the difference between the input pulse injected into a fiber and the output pulses exiting the fiber. The decrease in the height of the pulse shows the loss of optical signal power. The broadening of the pulse shows the bandwidth limiting effects of the fibers. It also shows the different paths of rays of light traveling down the fiber. And, it shows the relative index of refraction of the core and clad- ding for each type of fiber.

FIGURE 6.10-6 Optical fiber types. The core diameter and its refractive index characteristics determine the light propagation path or paths within the fiber’s core. (From AMP, Inc., copyright illustration, used with per- mission.)

 

 

 

Posted in Fiber Optic Transport, Types of Fiber-optic Material, Users Guide to Fiber Optic Video Transmission, Users Guides | 3 Comments

Join the Video over Fiber LinkedIn Group by Jim Jachetta

video fiber optic links

Please click to join the Video over Fiber LinkedIn group. This is a group for fiber optic video transmission and general fiber optic professionals to network and share ideas. The group will address and discuss the technology, news, and solutions for video transmission over fiber optic cable for applications in the Broadcast Television, Sports, News, Corporate Audiovisual and Government Agencies.

Discussions to include but not limited to: Introduction to Fiber Optics; Fiber Optic Medium; Snell’s Law; Optical Windows & Spectrum; Materials; Modes; Refractive Index; Dispersion; Early Applications; Multiplexing; CWDM; DWDM; Information Transmission; Modulation; Connectors; Splicing; Design; Bandwidth; Optic Loss; Trouble Shooting; Maintenance; Applications for Broadcast TV, Sports, Corporate AV and Military; Optical Repeaters; Optical Amplifiers; RF, Satellite and CATV over Fiber; Fiber Optic Routing Switchers; Photonic Fiber Optic Switchers; Electro-optical Routing Switchers; 3G HD SDI over Fiber; 4K over Fiber; The Future of Fiber and more…

Invite your friends, colleagues, partners, clients and vendors! We welcome your participation and feedback. Thank you.

Posted in Fiber Optic Transport, Jim Jachetta, Users Guide to Fiber Optic Video Transmission | Leave a comment

User’s Guide to Fiber Optic Video Transmission by Jim Jachetta

One of my favorite subjects is the transmission of video over fiber optic cable. I have had the pleasure of working on fiber optic implementations with Broadcasters to cover Presidential Elections and with Integrators on projects like the Las Vegas City Center.

Because of this passion, I am starting a multi-part series on the subject of Fiber Optic Video Transmission. My goal in writing this is to speak from my experience to make a topic that is scary to many, easy to understand and accessible so you can implement your own systems. I hope to do it in a humorous way relating my successes and challenges implementing many of these systems.

Anyone who knows me has also seen my passion for problem solving and doing the “impossible” and “never been done before”. I enjoy troubleshooting multi-million dollar fiber optic systems to discover a bad $20 patch cord or dirty fiber optic connector. The good news is that once a fiber optic system is up and running I know you will get many years of reliable operation.

In this series I will start with the basics and work my way up to the bleeding edge with 4K video fiber optic transmission. The series is perfect for the beginner and a good review for the expert. Clink these links to go to my first posts:

Users Guide to Fiber Optic Video Transmission

Introduction to Fiber Optics – Part 1

Snell’s Law – Part 2

Optical Windows and Spectrum – Part 3

I’ve had a great time putting this series on Fiber Optic Video Transmission together for you and I hope you get great insight and some practical tips for your particular situation. From time to time I may also show you some interesting fiber optic products you can take a look at like these two below. If you have any questions about any of the content you can reply to this email or contact me at 949-777-5435 x 1001.

SilverBack Fiber
FVT/FVR-5400-3G, VidOptic Series, 4 Channel 3G HDSDI Fiber Optic Transport Card with 4×4 Matrix for openGear SilverBack 4K & HD SDI Fiber Optic Camera Back Camera Mount System

Watch for my next installment in about 4 weeks. Please click to download additional white papers and presentations on wireless, webcasting, streaming and fiber optics. Thank you.

All the best,

Jim Jachetta
President and CEO
VidOvation Corporation
949-777-5435

Posted in Fiber Optic Medium, Fiber Optic Transport, Introduction to Fiber Optics, Optical Windows and Spectrum, Snells Law, Users Guide to Fiber Optic Video Transmission, Users Guides | Tagged , , , , | Leave a comment