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⚫ | The '''rusty bolt effect''' is a |
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⚫ | The '''rusty bolt effect''' is a form of radio interference due to interactions of the radio waves with dirty connections or corroded parts.<ref name=lui_1990>Lui, P.L., ''Passive intermodulation interference in communication systems,'' IEEE Electronics & Communication Engineering Journal, Vol. 2, No. 3, pp.109-118, Jun 1990. .</ref> It is more properly known as ''']''',<ref name=lui_1990/> and can result from a variety of different causes such as ferromagnetic conduction metals,<ref name=henrie_2009>Henrie, J., Christianson, A. and Chappell, W. ''Engineered passive nonlinearities for broadband passive intermodulation distortion mitigation,'' Microwave and Wireless Components Letters, Vol. 19, pp.614-616, 2009. .</ref> or nonlinear microwave absorbers and loads.<ref name=christianson_2009>Christianson, A. and Chappell, W. J. ''Measurement of ultra low passive intermodulation with ability to separate current/voltage induced nonlinearities,'' in IEEE Microwave Theory and Techniques Society International Microwave Symposium, Boston, MA, 2009, pp. 1301-1304. .</ref> Corroded materials on antennas, waveguides, or even structural elements, can act as one or more ]s. (]s, early radio receivers, used the semiconductor properties of natural ] to demodulate the radio signal, and ] was used in power rectifiers.) Galvanised fasteners and sheet roofing develop a coating of zinc oxide, a semiconductor commonly used for transient voltage suppression. This gives rise to undesired interference, including the generation of ]s or ].<ref>{{cite web |url=http://www.ofcom.org.uk/static/archive/ra/topics/research/RAwebPages/Radiocomms/pages/mittech/design/intermod.htm |title=Preventing intermodulation |accessdate=2011-02-13}}</ref> Rusty objects that should not be in the signal-path, including antenna structures, can also reradiate radio signals with ]s and other unwanted signals.<ref name=lui_1989>Lui, P.L.; Rawlins, A.D., ''The field measurement of passive intermodulation products.'' Fifth International Conference on Mobile Radio and Personal Communications, 1989. pp.199-203, 11-14 Dec 1989. .</ref> As with all out-of-band noise, these ]s can interfere with receivers. | ||
This effect can cause radiated signals out of the desired band, even if the signal into a passive antenna is carefully band-limited.<ref name=gps_1990>Johannessen, R.; Gale, S.J.; Asbury, M.J.A., ''Potential interference sources to GPS and solutions appropriate for applications to civil aviation.'' IEEE Aerospace and Electronic Systems Magazine, Vol. 5, No. 1, pp.3-9, Jan 1990 .</ref> |
This effect can cause radiated signals out of the desired band, even if the signal into a passive antenna is carefully band-limited.<ref name=gps_1990>Johannessen, R.; Gale, S.J.; Asbury, M.J.A., ''Potential interference sources to GPS and solutions appropriate for applications to civil aviation.'' IEEE Aerospace and Electronic Systems Magazine, Vol. 5, No. 1, pp.3-9, Jan 1990 .</ref> | ||
==Possible cures== | |||
If one experiences this problem, one should check both the transmitter and the television for dirty connections or corroded parts. One should also check for signs of ] in the cables which link the equipment to the antennae and for badly made joints. Beyond this, one might check any metal objects near the antenna for ] or corrosion. Any of these could be the source of the problem. | |||
It is possible to cure this problem in several ways: | |||
* Remove the corroded object. This is often the best cure because if you can eliminate the object then the interference it generates will cease entirely. | |||
* Clean the object - if the rust is superficial, the diode behavior might be eliminated by removing the surface rust. | |||
* Place an ] between the two objects which are causing the issue. This might reduce the RF current. | |||
* Lower the RF field strength. Intermodulation becomes much worse with amplitude, so small amplitude reduction can greatly reduce the intensity of the effect. See the mathematics section below for details. | |||
* Get a better antenna which is more ]. It may be possible to point the aerial in such a direction that it does not pick up the unwanted signal coming from the "rusty bolt." | |||
==Mathematics associated with the ''rusty bolt''== | ==Mathematics associated with the ''rusty bolt''== | ||
⚫ | The ] of an object can be represented as a ]: | ||
⚫ | :<math>E_\text{out} = \sum_{n=1}^\infty {K_n E_\text{in}^n}</math> | ||
⚫ | The ] of an object can be |
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<math> | |||
⚫ | E_{out} = \sum_{n=1}^\infty {K_n E_{in}^n} | ||
</math> | |||
Or, taking only the first few terms (which are most relevant), | Or, taking only the first few terms (which are most relevant), | ||
⚫ | :<math>E_\text{out} = K_1 E_\text{in} + K_2 E_\text{in}^2 + K_3 E_\text{in}^3 + K_4 E_\text{in}^4 + K_5 E_\text{in}^5 + ...</math> | ||
For an ideal perfect linear object K<sub>2</sub>, K<sub>3</sub>, K<sub>4</sub>, K<sub>5</sub>, etc. are all zero. A good connection approximates this ideal case with sufficiently small values. | |||
<math> | |||
⚫ | E_{out} = K_1 E_{in} + K_2 E_{in}^2 + K_3 E_{in}^3 + K_4 E_{in}^4 + K_5 E_{in}^5 + ... |
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</math> | |||
For an |
For a 'rusty bolt' (or an intentionally designed ] stage), K<sub>2</sub>, K<sub>3</sub>, K<sub>4</sub>, K<sub>5</sub>, etc. are not all zero. These higher-order terms result in generation of harmonics. | ||
⚫ | The following analysis applies the power series representation to an input sine-wave. | ||
For a 'rusty bolt' (or an intentionally designed ] stage), K<sub>2</sub>, K<sub>3</sub>, K<sub>4</sub> or K<sub>5</sub> etc. are not zero. These higher-order terms result in generation of harmonics. | |||
⚫ | The following analysis applies the |
||
===Harmonic generation=== | ===Harmonic generation=== | ||
If the incoming signal is a sine wave {E<sub>in</sub> sin(ωt)}, (and taking only first-order terms), then the output can be written: | If the incoming signal is a sine wave {E<sub>in</sub> sin(ωt)}, (and taking only first-order terms), then the output can be written: | ||
:<math>\begin{align} | |||
E_\text{out} &= \sum_{i = 1}^\infty {K_i E_\text{in}^i \sin(i \omega t)} \\ | |||
⚫ | &= K_1 E_\text{in} \sin(\omega t) + K_2 E_\text{in}^2 \sin(2\omega t) + K_3 E_\text{in}^3 \sin(3\omega t) + K_4 E_\text{in}^4 \sin(4\omega t) + K_5 E_\text{in}^5 \sin(5\omega t) + \cdots | ||
\end{align}</math> | |||
⚫ | Clearly, the harmonic terms will be worse at high input signal amplitudes, as they increase exponentially with the amplitude of ''E''<sub>in</sub>. | ||
<math> | |||
⚫ | |||
</math> | |||
⚫ | Clearly, the harmonic terms will be worse at high input signal amplitudes, as they increase |
||
===Mixing product generation=== | ===Mixing product generation=== | ||
====Second order terms==== | |||
To understand the generation of nonharmonic terms (]), a more complete formulation must be used, including higher-order terms. |
To understand the generation of nonharmonic terms (]), a more complete formulation must be used, including higher-order terms. These terms, if significant, give rise to ] distortion. | ||
:<math>\begin{align} | |||
⚫ | E_{f_1 + f_2} &= k E_{f_1} E_{f_2}\\ | ||
<math> | |||
E_{f_1 |
E_{f_1 - f_2} &= k E_{f_1} E_{f_2} | ||
</math> | \end{align}</math> | ||
<math> | |||
⚫ | E_{f_1 |
||
</math> | |||
⚫ | |||
<math> | |||
⚫ | E_{f_1+f_2+f_3} = k E_{f_1} |
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</math> | |||
<math> | |||
⚫ | E_{f_1-f_2 |
||
</math> | |||
<math> | |||
⚫ | E_{f_1+f_2-f_3} = k E_{f_1} |
||
</math> | |||
⚫ | ====Third order terms==== | ||
<math> | |||
:<math>\begin{align} | |||
⚫ | E_{f_1-f_2 |
||
⚫ | E_{f_1 + f_2 + f_3} &= k E_{f_1} E_{f_2} E_{f_3} \\ | ||
</math> | |||
⚫ | E_{f_1 - f_2 + f_3} &= k E_{f_1} E_{f_2} E_{f_3} \\ | ||
⚫ | E_{f_1 + f_2 - f_3} &= k E_{f_1} E_{f_2} E_{f_3} \\ | ||
⚫ | E_{f_1 - f_2 - f_3} &= k E_{f_1} E_{f_2} E_{f_3} | ||
\end{align}</math> | |||
Hence the second |
Hence the second-order, third-order, and higher-order mixing products can be greatly reduced by lowering the intensity of the original signals (f<sub>1</sub>, f<sub>2</sub>, f<sub>3</sub>, f<sub>4</sub>, …, f<sub>n</sub>) | ||
==References== | ==References== |
Latest revision as of 06:09, 19 September 2024
The rusty bolt effect is a form of radio interference due to interactions of the radio waves with dirty connections or corroded parts. It is more properly known as passive intermodulation, and can result from a variety of different causes such as ferromagnetic conduction metals, or nonlinear microwave absorbers and loads. Corroded materials on antennas, waveguides, or even structural elements, can act as one or more diodes. (Crystal sets, early radio receivers, used the semiconductor properties of natural galena to demodulate the radio signal, and copper oxide was used in power rectifiers.) Galvanised fasteners and sheet roofing develop a coating of zinc oxide, a semiconductor commonly used for transient voltage suppression. This gives rise to undesired interference, including the generation of harmonics or intermodulation. Rusty objects that should not be in the signal-path, including antenna structures, can also reradiate radio signals with harmonics and other unwanted signals. As with all out-of-band noise, these spurious emissions can interfere with receivers.
This effect can cause radiated signals out of the desired band, even if the signal into a passive antenna is carefully band-limited.
Mathematics associated with the rusty bolt
The transfer characteristic of an object can be represented as a power series:
Or, taking only the first few terms (which are most relevant),
For an ideal perfect linear object K2, K3, K4, K5, etc. are all zero. A good connection approximates this ideal case with sufficiently small values.
For a 'rusty bolt' (or an intentionally designed frequency mixer stage), K2, K3, K4, K5, etc. are not all zero. These higher-order terms result in generation of harmonics.
The following analysis applies the power series representation to an input sine-wave.
Harmonic generation
If the incoming signal is a sine wave {Ein sin(ωt)}, (and taking only first-order terms), then the output can be written:
Clearly, the harmonic terms will be worse at high input signal amplitudes, as they increase exponentially with the amplitude of Ein.
Mixing product generation
Second order terms
To understand the generation of nonharmonic terms (frequency mixing), a more complete formulation must be used, including higher-order terms. These terms, if significant, give rise to intermodulation distortion.
Third order terms
Hence the second-order, third-order, and higher-order mixing products can be greatly reduced by lowering the intensity of the original signals (f1, f2, f3, f4, …, fn)
References
- ^ Lui, P.L., Passive intermodulation interference in communication systems, IEEE Electronics & Communication Engineering Journal, Vol. 2, No. 3, pp.109-118, Jun 1990. Available online.
- Henrie, J., Christianson, A. and Chappell, W. Engineered passive nonlinearities for broadband passive intermodulation distortion mitigation, Microwave and Wireless Components Letters, Vol. 19, pp.614-616, 2009. Available online.
- Christianson, A. and Chappell, W. J. Measurement of ultra low passive intermodulation with ability to separate current/voltage induced nonlinearities, in IEEE Microwave Theory and Techniques Society International Microwave Symposium, Boston, MA, 2009, pp. 1301-1304. Available online.
- "Preventing intermodulation". Retrieved 2011-02-13.
- Lui, P.L.; Rawlins, A.D., The field measurement of passive intermodulation products. Fifth International Conference on Mobile Radio and Personal Communications, 1989. pp.199-203, 11-14 Dec 1989. Available online.
- Johannessen, R.; Gale, S.J.; Asbury, M.J.A., Potential interference sources to GPS and solutions appropriate for applications to civil aviation. IEEE Aerospace and Electronic Systems Magazine, Vol. 5, No. 1, pp.3-9, Jan 1990 Available online.