In week 6 we started to produce material for our poster. The aim is to collect information about fiber optics collaboratively. The topics for different teams are presented in Wiki-page: Optical fibers.
Using the collaborative inquiry technique, produce a first draft of your wiki page. Next week we study the pages more carefully and continue processing them.
Transparency (Thai)
Decibel (Binh)
Amplifiers / optical (Minh)
frequency (Phat)
depending variables (Phat)
-------------------------------------------------------------------------------
Background
What questions did the video/demo/simulation, etc. arise?
What questions did you pick up for further investigation?
Initial questions
How does it work …., what happens here, why ...?
Selected problem
What questions did you select to work in more details?
My explanation (original hypothesis)
What is your own explanation for your questions?
Critical evaluation
What strengths and weaknesses does your explanation have?
What I need to find out more?
How could I improve my explanation?
What do you not understand or know yet about this topic?
Finding more information
First you can list all the references to the additional material you find out in order to use them later.
Then try to understand what does it say about the problem.
Use your own language to explain the things. Don’t copy and paste text.
Use graphs and equations to illustrate
Additional questions
What new questions arised based on the new information?
How, what, why?
My new theories
Now I believe that …
You can continue the loop critical evaluation, finding more information, new questions, etc… in the given time limit.
Summary
In your own words, explain what have you done and what have you found. Evaluate critically how good your theory is. Compare to the information you find from the internet.
Background
The requirement is understand amplifier definition in optical fiber domain.
Initial questions
What is amplifier?
What is the roll of amplifier in optical fiber study?
Selected problem
All questions were selected to answer in detail.
My explanation
Amplification is required to solve the problem of degradation of signal transmitting in optical fibers.
Critical evaluation
More details and reading as well as reasoning that need to be provided.
Finding more information
Reading more in Fiber optics engineering of Mohammad Azadeh.
Final theory
Optical link has limit in range as there is always attenuation of propagating light in a normal fiber. One method to solve the problem is detect the optical signal before the critical low value and covert it back to electrical domain and create new copy of optical signal. Another method is using optical amplifier. Without need of converting back optical signal to electrical domain, an amplifier can be used in different applications. It can be use as an inline amplifiers to compensate the attenuation of optical signals as well as pre-amplifiers in optical detectors to improve sensitivity of the receiver or as power boosters to raise output power of an optical transmitter.[1,149]
There are two categories of amplifiers: semiconductor optical amplifiers (SOAs) and fiber amplifiers. Optical gain in semiconductors is based on forward-biased junction. Fiber amplifier contains optical fiber which is doped with a rare earth element such as neodymium (Nd) and praseodymium (pr) etc… The existence of dopants creates new energy bands within the fiber.
Figure1: Band diagram of a doped fiber amplifier. Copied from Azadeh, M. (2009). Fiber optics engineering.[1,150]
Figure 1 illustrates the dopants ions interact with the pump signal with frequency fp and goes to higher energy state Ep . The ions have short lifetime ( Tp ) and quickly move to lower energy band, Et , in which they have longer lifetime ( Tl ). Because Tl >> Tp , population inversion is created. Inverted system interacts with main signal of frequency f , results in amplification of signal as stimulated emission happens.
The erbium doped fiber amplifier (EDFA) is the most popular type as El – Eo exists in the wavelength of 1550 nm. In consequence, EDFA can amplify signal in lowest range of attenuation of silica fibers, results in the popularity of using in long distance communication. Typical EDFA amplifiers can supply gain in 30nm band (1530-1560 nm) with gain of 20-30 dB.
Figure 2: Sample EDFA configuration. Copied from Azadeh, M. (2009). Fiber optics engineering.[1,151]
Figure 2 shows one example of co-directional pumping as the main and pump signals travel in same direction. EDFAs have very important role in long-range optical fiber communication, and subjected to high interest of researching for increase of bandwidth and performance.
Decibel
Background
The requirement is to understand what is decibel and what it is used for
Initial questions
- What is decibel?
2. How to measure it?
3. How to use it in optical fiber ?
Selected problem
All questions were selected to answer in detail.
My explanation
- Decibel is a universal unit to measure sound level, but it is also used in electronics, signals and communications.
- On the decibel scale, the smallest audible sound (near total silence) is 0 dB. A sound 10 times more powerful is 10 dB. A sound 100 times more powerful than near total silence is 20 dB.
- In my opinion, decibel is used to measure signal loss in transmission in optical fiber.
Critical evaluation
More details and reading as well as reasoning that need to be provided.
Finding more informationLooking for more info about Decibel and also how to use it in fiber optic
Final theory:
The decibel (dB) is used to measure sound level but it is also used widely in communications, electronics and signals. In communications, the decibel is a logarithm way of describing a ratio between two signal power, such as power, sound pressure, voltage, or current levels The decibel is a common measurement used in the field of electronics to determine loss or gain in a system.
Suppose we have 2 signals, signal 1 has a power of P1 watts, signal 2 has a power of P2 Watts, then the difference in decibels between 2 signals is defined to be:
10log(P2/P1)dB where the log is base 10
In order to measure optical loss, you can use two units, namely, dBm and dB. While dBm is the actual power level represented in milliwatts, dB (decibel) is the difference between the powers.
Figure 4 – How to Measure Optical Power
Figure 1: How to measure optical power [1]
Light loss, L(dB), is a commonly used specification for fiber optic attenuation. For example, to determine the light loss of an optical fiber in a cable, a light source is connected to one end of the fiber cable (input). The light output power of the source is known to be 0.1 mW. When an optical power meter is connected to the opposite end of the fiber optic cable under test (output), the meter measures 0.05 mW. Using the decibel power loss formula, the optical fiber loss can be calculated as follows:
Figure 2: How to measure fiber loss [2]
The light power loss of this optical fiber is 3 dB
The dB unit is a logarithmic ratio of input and output levels and is therefore not absolute (i.e., has no units). An absolute measure of power in decibels can be made in the dBm form. The dBm unit is a logarithmic ratio of the measured power to 1 mW of reference power
Reference
- Introduction to optical fibers, dB, Attenuation and measurement:
http://www.cisco.com/c/en/us/support/docs/optical/synchronous-digital-hierarchy-sdh/29000-db-29000.html - Optical Power loss measurement in db- how to measure it fast and correct
http://www.ad-net.com.tw/?id=474
-----------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------
Frequency
Background
The requirement is to understand what factors and dependencies cause attenuation in fiber optic.
Initial questions
Selected problem
My explanation
Attenuation has relation in increasing with frequency, which means the higher the frequency the higher the attenuation.
Critical evaluation
More details and reading as well as reasoning that need to be provided.
Finding more information
More information is obtained by reading books and searching for online information.
Final theory
Attenuation always serves as a measurement parameter that leads to the formation of theories to explain physical or chemical phenomenon, which decreases the ultrasonic intensity. Attenuation is generally proportional to the square of sound frequency. Quoted values of attenuation are often given for a single frequency, or an attenuation value averaged over many frequencies may be given. The attenuation coefficient (α) can be used to determine total attenuation in dB in the medium using the following formula:
The attenuation coefficients of common biological materials at a frequency of 1 MHz are listed below:
Material | α(dB/(MHz·cm)) |
---|---|
Air | 1.64 (20°C) |
Blood | 0.2 |
Bone, cortical | 6.9 |
Bone, trabecular | 9.94 |
Brain | 0.6 |
Breast | 0.75 |
Cardiac | 0.52 |
Connective tissue | 1.57 |
Dentin | 80 |
Enamel | 120 |
Fat | 0.48 |
Liver | 0.5 |
Marrow | 0.5 |
Muscle | 1.09 |
Tendon | 4.7 |
Soft tissue (average) | 0.54 |
Water | 0.0022 |
Figure 1. Diffuse reflection. Copied from [1]
- Culjat, Martin O.; Goldenberg, David; Tewari, Priyamvada; Singh, Rahul S. (2010). "A Review of Tissue Substitutes for Ultrasound Imaging". Ultrasound in Medicine & Biology 36 (6): 861–873.
- Tole, Nimrod M. (2005). Basic physics of ultrasonographic imaging.
Chapter 3: http://www.isradiology.org/isr/docs_books/basic/Chapter3.pdf