Introduction to otdr
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This white paper introduces the optical time-domain reflectometer (OTDR), a key instrument for testing and certifying optical fibers in premise networks by locating defects and measuring signal loss. It discusses important specifications for selecting an OTDR, including dynamic range, dead zones, resolution, and the benefit of pass/fail thresholds, as well as post-processing capabilities. Additionally, the document emphasizes the importance of matching OTDR capabilities with specific testing applications and user needs.
Introduction to otdr
- 1. WHITE PAPER Fiberstore White Paper | Introduction to OTDR 1 As the use of fiber in premise networks continues to grow, so do the requirements for testing and certifying it. An optical time-domain reflectometer (OTDR) is an electronic-optical instrument used to characterize optical fibers. It locates defects and faults, and determines the amount of signal loss at any point in an optical fiber. This article describes how an OTDR works and the key specifications that should be considered when choosing an OTDR. How Does an OTDR Work? An OTDR uses the effects of Rayleigh scattering and Fresnel reflection to measure the characteristics of an optical fiber. By sending a pulse of light into a fiber and measuring the travel time (“time domain”) and strength of its reflections (“reflectometer”) from points inside the fiber, it produces a characteristic trace, or profile, of the length vs. returned signal level on a display screen. The working principle of OTDR is based on Rayleigh scattering, a small fraction of light spreading in all direction, which is caused when a light pulse encounters the faults and heterogeneity in optical fiber. (as shown in the following picture.) OTDR Selection Guide Introduction to OTDR
- 2. WHITE PAPER Fiberstore White Paper | Introduction to OTDR 2 When choosing an OTDR, it is important to select the specific OTDR performance and features according to the required specifications listed below. Dynamic Range The dynamic range of an OTDR determines how long of a fiber can be measured. The total optical loss that an OTDR can analyze is mainly determined by the dynamic range. The dynamic range affects the accuracy of the link loss, attenuation and far-end connector losses. Thus, having sufficient dynamic range is really important. The manufacturers specify dynamic range in different way. The higher the dynamic range, the longer the distance an OTDR can analyze. Dead Zones Dead zone refers to the space on a fiber trace following a Fresnel reflection in which the high return level of the reflection covers up the lower level of backscatter. To specify an OTDR’s performance, it is important to analyze the dead zone and ensure the whole link is measured. Dead zones are characterized as an event dead zone and an attenuation dead zone. Event dead zone refers to the minimum distance required for consecutive reflective events to be “resolved” (for example, to be differentiated from each other). Attenuation dead zone refers to the minimum distance required, after a reflective event, for the OTDR to measure a reflective or non-reflective event loss. Resolution There are two resolution specifications: loss (level), and spatial (distance). Loss resolution is the ability of the sensor to distinguish between levels of power it receives. When the laser pulse gets farther out in the fiber, the corresponding backscatter signal gets weaker and the difference between backscatter levels from two adjacent measurement points becomes larger. Spatial resolution is how close the individual data points that make up a trace are spaced in time (and corresponding distance). The OTDR controller samples the sensor at regular time intervals to get the data points. If it takes readings from the sensor very frequently, then the data points will be spaced close together and the OTDR can detect events in the fiber that are closely spaced. Pass/Fail Thresholds This is an important feature because a great deal of time can be saved in the analysis of OTDR traces if the user is able to set pass/fail thresholds for parameters of interest (such as splice loss or connector reflection). These thresholds highlight parameters that have exceeded a warning or fail limit set by the user and, when used in conjunction with reporting software, it can rapidly provide re-work sheets for installation/commissioning engineers. Post-Processing and Reporting Report generation could be another major time saver. For example, some OTDRs with specialized post-processing software allow fast and easy report generation, which might reduce the post-processing time up to 90 percent. These reports also include bidirectional analyses of OTDR traces and summary reports for high-fiber-count cables. Your Applications and Users Some OTDRs are designed to test long distance optical fibers and some others to test short distance
- 3. WHITE PAPER Fiberstore White Paper | Introduction to OTDR 3 optical fibers. For example, if you are to test premises fiber networks where short distance optical fibers are installed, OTDRs designed for testing long distance optical fibers are not suitable. Besides, knowing your users and the time it will cost is also necessary. Because some types of OTDRs are easy to use and some others are complicated to set up. When selecting an OTDR, you’re supposed to take all the above factors into consideration. Fiberstore supplies a wide range of OTDRs available with various fiber types and wavelengths (including single-mode fiber, multi-mode fiber, 1310nm, 1550 nm, 1625 nm, etc). They also supply OTDRs of famous brands, such as JDSU MTS series, EXFO FTB series, YOKOGAWA AQ series and so on. OEM portable and handheld OTDRs are available as well. Contact Us Manufacturing R & D (China) Eastern Side, Second Floor, Science & Technology Park, No.6, Keyuan Road, Nanshan District, Shenzhen 518057, China Tel: +86 (755) 8300 3611 Fax: +86 (755) 8326 9395 Email: [email protected] APAC Office (Hong Kong) 1220 Tung Chun Commercial Centre, 438-444 Shanghai Street, Kowloon, HongKong Tel: +852 81763606 Fax: +852 81763606 Email: [email protected] North America (United States) 331 Andover Park East Ste330, Tukwila, WA 98188,United States Tel: +1-425-226-2035 Fax: +1-253-246-7881 Email: [email protected] London Office (United Kingdom) Third Floor 207 Regent Street, London, W1B 3HH, United Kingdom Tel: +44 2081441980 Notice: This document is for informational purposes only and does not set forth any warranty, expressed or implied, concerning any equipment, equipment features, or service offered or to be offered by Fiberstore. Fiberstore reserves the right to make changes to this document at any time, without notice, and assumes no responsibility for its use. This information document describes features that may not be currently available. Contact a Fiberstore sales team for information on feature and product availability. Follow us LinkedIn Twitter Facebook G+ Pinterest Youtube Blog