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How to use a simple SWR meter and what it means to your VHF
You need to tune your tuner only to provide the proper impedance match
to your transmitter. A 50 ohm SWR bridge at the transmitter will tell you when you have achieved that. Swr on the feed line matters very little. SWR at the fixed 50 ohm output port of your transmitter matters allot. The networks inside your transmitter that provide the impedance match between your final amplifiers and the 50 ohm output port are fixed. They are not adjustable to match any other load. If you do not provide the proper 50 ohm load to the transmitter then the finals can draw excessive current and damage them. At the same time you may not have the proper impedance match to the finals that allow the transmitter to put out its designed power. As long as the transmitter with its fixed 50 ohm output sees a 50 ohm load it is happy. It doesn't matter what is happening in the feed line. If you have an antenna and a feed line that has a 3:1 SWR on it at the transmitter end the transmitter will not perform properly. If you place a matching device (tuner) between the transmitter and that feed line and tune it so that the transmitter sees a pure 50 ohms, then the transmitter is completely happy. But the feed line still has that same 3:1 SWR on it. 25% reflected power from the antenna. Place your SWR bridge between the tuner and the feed line and you will see it. Does that mean that 25% of the power is wasted? Where does it go? We just adjusted the tuner so that there was no SWR on the transmitter so it isn't going there. Put a watt meter at the antenna end of the feed line and guess what? You will see the full transmitter power there. Providing of course you don't have a high loss coax line. If the SWR on a coax line gets too high then there are going to be more cable losses due to excessive currents in the line. That is why open wire feed line has much less loss than coax. Because its impedance is higher the current is less for a given amount of power and you have less IR loss. RG 8 cable has less loss than RG 58. The RG 8 has bigger conductors so less resistance. If you use a cable with larger conductors or one with a higher impedance you will have less loss. As I mentioned before, with open wire line you can feed a dipole antenna on many bands and have very high SWR on the fed line and have negligible loss on the feed line. Look in your hand book on multi band antennas fed with open wire line. I keep mentioning open wire line only because it serves as a good example of systems often used with high SWR on the line with almost no loss. The same holds true for coax line but there is less written on it. And coax being a lower impedance will have higher currents and thus more inherent loss for a given amount of power. Regards Gary On Fri, 21 Nov 2003 09:18:38 -0500, "Doug Dotson" wrote: If SWR doesn't matter, then why do I need to tune my antenna or use an automatic tuner if all the reflectedd power eventually gets radiated? Why did my finals burn up when I keyed up into a very poorly mismatched antenna. Doug, k3qt s/v Callista "Larry W4CSC" wrote in message ... Ok, you go on believing that......... On Thu, 20 Nov 2003 18:02:21 GMT, Gary Schafer wrote: Simply not true?? You need to do some more reading Larry. A good start would be Walter Maxwell's book "reflections". It is explained there well. Even the later handbooks touch on the subject. First, impedance does not "absorb any reflected power". Reflected power on the antenna line DOES NOT go back into the final amplifier and get dissipated. That is an old wives tale that is probably older than all of us. The reason for "being careful" on a high power transmitter with reflected power is that the voltages can become very high due to the high impedance's involved in the tank circuit. Also circulating currents can become high in the matching components. Thus stressing the circuit components. But no great amount of reflected power is absorbed by anything. Ever look at the color of the plates on a high power transmitter working into a normal load verses a high SWR load? When tuned for the same power level in both cases there is no difference in plate color. If reflected power were being dissipated in the final plates they would be hotter, indicated by a hotter color. If you think that the tank coil in your 50 kw transmitter is going to dissipate 5 kw in heat,, then watch it glow red. But we both know it doesn't, right? With solid state amplifiers there is the problem of transistors not liking to work into complex impedance's. It causes them to draw very high currents. Nothing to do with absorbing reflected power. Have you ever used open wire feeders to an antenna? The SWR on the feed line can be very high. It can be in the order of 15 or 20:1 on the line depending on the antenna type and frequency being used. But there is almost no additional loss on the line over the line being 1:1. What do you think happens to all that reflected power on that feed line? Where do you think it gets dissipated? Hint, it all gets radiated. Regards Gary On Thu, 20 Nov 2003 12:38:22 GMT, (Larry W4CSC) wrote: On Thu, 20 Nov 2003 03:50:41 GMT, Gary Schafer wrote: SWR in itself is not necessarily bad. Power reflected back toward the transmitter is not lost as a result of the reflection itself. When that reflected power hits the transmitter it is re-reflected back up to the antenna. Simply not true. The source impedance of the output power amplifier is, ideally 50 ohms to match the cable. This impedance absorbs reflected power, converting it into heat in its resistive component which is lost. The output matching network of the transmitter is tuned to make it look resistive. Almost nothing is reflected, again. At 150W with a couple of watts reflected, it's a no-brainer. However, if you are running a 50KW broadcast transmitter, reflected power greatly increases the transmitter's output amp heating problems so they are very careful with it. A 2:1 SWR means we have another 5000 watts of heat to cool off the finals, cooking them. The normally hot finals simply cook themselves. So a 3:1 swr with 6.25 watts of reflected power and 25 watts of forward power, still delivers 25 watts to the antenna to be radiated. That is of course when there is no feed line loss. Too bad this isn't true. If the final amp were purely reactive, it would be, but then there would be no match between the transmitter and feed line to begin with so there'd be no power output if it were purely reactive. With feed line loss involved (as there always is) you will get a false SWR reading. The more loss your cable has the better your SWR will look. Finally something that is true. SWR should be measured at the antenna if the line is long and lossy. However, this isn't that important in a boat with 50' of RG-58 at VHF. 73 de Larry W 4 C S C h h o a i a u r s r t o k l h l e e i y s n t a o n NNNN Larry W4CSC NNNN |
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How to use a simple SWR meter and what it means to your VHF
"Gary Schafer" wrote in message
... You need to tune your tuner only to provide the proper impedance match to your transmitter. A 50 ohm SWR bridge at the transmitter will tell you when you have achieved that. Swr on the feed line matters very little. snip If you have an antenna and a feed line that has a 3:1 SWR on it at the transmitter end the transmitter will not perform properly. If you place a matching device (tuner) between the transmitter and that feed line and tune it so that the transmitter sees a pure 50 ohms, then the transmitter is completely happy. But the feed line still has that same 3:1 SWR on it. 25% reflected power from the antenna. You obviously don't understand how this works. The combination of antenna and feedline presents a certain impedance at the end of the feedline. What the tuner does is transform the 50 Ohm on the TX side to the impedance on the feedline. And when this all matches, there is no SWR. Neither on the TX side of the tuner, nor on the feedline side. Meindert pe1grv |
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How to use a simple SWR meter and what it means to your VHF
On Fri, 21 Nov 2003 20:12:32 +0100, "Meindert Sprang"
wrote: "Gary Schafer" wrote in message .. . You need to tune your tuner only to provide the proper impedance match to your transmitter. A 50 ohm SWR bridge at the transmitter will tell you when you have achieved that. Swr on the feed line matters very little. snip If you have an antenna and a feed line that has a 3:1 SWR on it at the transmitter end the transmitter will not perform properly. If you place a matching device (tuner) between the transmitter and that feed line and tune it so that the transmitter sees a pure 50 ohms, then the transmitter is completely happy. But the feed line still has that same 3:1 SWR on it. 25% reflected power from the antenna. You obviously don't understand how this works. The combination of antenna and feedline presents a certain impedance at the end of the feedline. What the tuner does is transform the 50 Ohm on the TX side to the impedance on the feedline. And when this all matches, there is no SWR. Neither on the TX side of the tuner, nor on the feedline side. Meindert pe1grv Wann bet? :) Try it some time. Tune the tuner so there is no SWR at the transmitter. Then place the SWR meter between the tuner and the transmission line. You will still see the same SWR that you started with! There is nothing you can do at the transmitter end of the transmission line to change the impedance or the SWR on the transmission line. That can only be done at the antenna end of the line. Regards Gary |
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How to use a simple SWR meter and what it means to your VHF
"Gary Schafer" wrote in message
... On Fri, 21 Nov 2003 20:12:32 +0100, "Meindert Sprang" You obviously don't understand how this works. The combination of antenna and feedline presents a certain impedance at the end of the feedline. What the tuner does is transform the 50 Ohm on the TX side to the impedance on the feedline. And when this all matches, there is no SWR. Neither on the TX side of the tuner, nor on the feedline side. Meindert pe1grv Wann bet? :) Try it some time. Tune the tuner so there is no SWR at the transmitter. Then place the SWR meter between the tuner and the transmission line. You will still see the same SWR that you started with! Of course you will. That's because you put the SWR meter on a place where the impedance is not 50 Ohm anymore. So now you have a mismatch between the feedline and 50 Ohm directional coupler in the SWR meter. Meindert |
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How to use a simple SWR meter and what it means to your VHF
On Sat, 22 Nov 2003 08:11:49 +0100, "Meindert Sprang"
wrote: "Gary Schafer" wrote in message .. . On Fri, 21 Nov 2003 20:12:32 +0100, "Meindert Sprang" You obviously don't understand how this works. The combination of antenna and feedline presents a certain impedance at the end of the feedline. What the tuner does is transform the 50 Ohm on the TX side to the impedance on the feedline. And when this all matches, there is no SWR. Neither on the TX side of the tuner, nor on the feedline side. Meindert pe1grv Wann bet? :) Try it some time. Tune the tuner so there is no SWR at the transmitter. Then place the SWR meter between the tuner and the transmission line. You will still see the same SWR that you started with! Of course you will. That's because you put the SWR meter on a place where the impedance is not 50 Ohm anymore. So now you have a mismatch between the feedline and 50 Ohm directional coupler in the SWR meter. Meindert Then how do you know that there ISN't any reflected power there when you tune as you say? What do YOU measure it with?? You are right about the impedance seen at that point being different because of the reflection but the CHARACTERISTIC IMPEDANCE of the line has NOT changed and that is the important point. Here is something for you guys with Bird watt meters to do to prove to yourself what happens with reflected power. Get out your little manual that came with your Bird through line meter. If you don't have one go on line and look. I think Bird has that manual online. It will tell you how to determine how much power is delivered to the load (antenna). "The characteristic impedance of the coax line must be the same as that of the Bird meter (50 ohms). Subtract the reflected power reading you get from the forward power reading you get. That is the power delivered to the load." This holds true for any load as long as your line is a 50 ohm line. Still don't believe? Try this. With no tuner in your transmission line tune your radio to a frequency where you see a high SWR. It doesn't matter what it is. 80 meters if you have it is a good place to do this as antenna bandwidth is rather narrow there. You can do this at any power level that your radio is comfortable with. Hook up your antenna tuner in the coax line as I have described before. Place your Watt meter between the transmitter and tuner. Tune the tuner for minimum reflected power to the radio. Note the forward power reading on the watt meter. Don't touch the power level on the radio. Replace the watt meter with any SWR bridge you might have around. Set the control on the SWR meter for full scale indication. This will be so you can achieve the same power out for the next step. Now place the watt meter between the tuner and the antenna. Turn on the transmitter and be sure that the SWR bridge reads the same as it did before. This tells you that you still have the same power out of the transmitter and that the tuner is still matched to the radio. Now look at the watt meter! If you have a 3:1 SWR on the antenna line and you had set up the radio for 100 watts out at the radio previously with the tuner in line, the watt meter at the antenna side will read 125 watts forward with 25 watts reflected!! Now do as the Bird manual tells you: Subtract the reflected reading from the forward reading. It should equal 100 watts. The same amount of power that the transmitter is putting out. All you doubting Larry's please try this and report back what you find. Then tell us why reflected power is not re-reflected back to the antenna if you can. :) Regards Gary |
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How to use a simple SWR meter and what it means to your VHF
On Sat, 22 Nov 2003 08:11:49 +0100, "Meindert Sprang"
wrote: "Gary Schafer" wrote in message .. . On Fri, 21 Nov 2003 20:12:32 +0100, "Meindert Sprang" You obviously don't understand how this works. The combination of antenna and feedline presents a certain impedance at the end of the feedline. What the tuner does is transform the 50 Ohm on the TX side to the impedance on the feedline. And when this all matches, there is no SWR. Neither on the TX side of the tuner, nor on the feedline side. Meindert pe1grv Wann bet? :) Try it some time. Tune the tuner so there is no SWR at the transmitter. Then place the SWR meter between the tuner and the transmission line. You will still see the same SWR that you started with! Of course you will. That's because you put the SWR meter on a place where the impedance is not 50 Ohm anymore. So now you have a mismatch between the feedline and 50 Ohm directional coupler in the SWR meter. Meindert Exactly the same thing you started with isn't it! Regards Gary |
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How to use a simple SWR meter and what it means to your VHF
Humm. I guess I need to contact the ARRL and make arrangements
to return all the Antenna Handbooks and Radio Amateur Handbooks I've accumulated over the past 30 years. Doug, k3qt s/v Callista "Gary Schafer" wrote in message ... You need to tune your tuner only to provide the proper impedance match to your transmitter. A 50 ohm SWR bridge at the transmitter will tell you when you have achieved that. Swr on the feed line matters very little. SWR at the fixed 50 ohm output port of your transmitter matters allot. The networks inside your transmitter that provide the impedance match between your final amplifiers and the 50 ohm output port are fixed. They are not adjustable to match any other load. If you do not provide the proper 50 ohm load to the transmitter then the finals can draw excessive current and damage them. At the same time you may not have the proper impedance match to the finals that allow the transmitter to put out its designed power. As long as the transmitter with its fixed 50 ohm output sees a 50 ohm load it is happy. It doesn't matter what is happening in the feed line. If you have an antenna and a feed line that has a 3:1 SWR on it at the transmitter end the transmitter will not perform properly. If you place a matching device (tuner) between the transmitter and that feed line and tune it so that the transmitter sees a pure 50 ohms, then the transmitter is completely happy. But the feed line still has that same 3:1 SWR on it. 25% reflected power from the antenna. Place your SWR bridge between the tuner and the feed line and you will see it. Does that mean that 25% of the power is wasted? Where does it go? We just adjusted the tuner so that there was no SWR on the transmitter so it isn't going there. Put a watt meter at the antenna end of the feed line and guess what? You will see the full transmitter power there. Providing of course you don't have a high loss coax line. If the SWR on a coax line gets too high then there are going to be more cable losses due to excessive currents in the line. That is why open wire feed line has much less loss than coax. Because its impedance is higher the current is less for a given amount of power and you have less IR loss. RG 8 cable has less loss than RG 58. The RG 8 has bigger conductors so less resistance. If you use a cable with larger conductors or one with a higher impedance you will have less loss. As I mentioned before, with open wire line you can feed a dipole antenna on many bands and have very high SWR on the fed line and have negligible loss on the feed line. Look in your hand book on multi band antennas fed with open wire line. I keep mentioning open wire line only because it serves as a good example of systems often used with high SWR on the line with almost no loss. The same holds true for coax line but there is less written on it. And coax being a lower impedance will have higher currents and thus more inherent loss for a given amount of power. Regards Gary On Fri, 21 Nov 2003 09:18:38 -0500, "Doug Dotson" wrote: If SWR doesn't matter, then why do I need to tune my antenna or use an automatic tuner if all the reflectedd power eventually gets radiated? Why did my finals burn up when I keyed up into a very poorly mismatched antenna. Doug, k3qt s/v Callista "Larry W4CSC" wrote in message ... Ok, you go on believing that......... On Thu, 20 Nov 2003 18:02:21 GMT, Gary Schafer wrote: Simply not true?? You need to do some more reading Larry. A good start would be Walter Maxwell's book "reflections". It is explained there well. Even the later handbooks touch on the subject. First, impedance does not "absorb any reflected power". Reflected power on the antenna line DOES NOT go back into the final amplifier and get dissipated. That is an old wives tale that is probably older than all of us. The reason for "being careful" on a high power transmitter with reflected power is that the voltages can become very high due to the high impedance's involved in the tank circuit. Also circulating currents can become high in the matching components. Thus stressing the circuit components. But no great amount of reflected power is absorbed by anything. Ever look at the color of the plates on a high power transmitter working into a normal load verses a high SWR load? When tuned for the same power level in both cases there is no difference in plate color. If reflected power were being dissipated in the final plates they would be hotter, indicated by a hotter color. If you think that the tank coil in your 50 kw transmitter is going to dissipate 5 kw in heat,, then watch it glow red. But we both know it doesn't, right? With solid state amplifiers there is the problem of transistors not liking to work into complex impedance's. It causes them to draw very high currents. Nothing to do with absorbing reflected power. Have you ever used open wire feeders to an antenna? The SWR on the feed line can be very high. It can be in the order of 15 or 20:1 on the line depending on the antenna type and frequency being used. But there is almost no additional loss on the line over the line being 1:1. What do you think happens to all that reflected power on that feed line? Where do you think it gets dissipated? Hint, it all gets radiated. Regards Gary On Thu, 20 Nov 2003 12:38:22 GMT, (Larry W4CSC) wrote: On Thu, 20 Nov 2003 03:50:41 GMT, Gary Schafer wrote: SWR in itself is not necessarily bad. Power reflected back toward the transmitter is not lost as a result of the reflection itself. When that reflected power hits the transmitter it is re-reflected back up to the antenna. Simply not true. The source impedance of the output power amplifier is, ideally 50 ohms to match the cable. This impedance absorbs reflected power, converting it into heat in its resistive component which is lost. The output matching network of the transmitter is tuned to make it look resistive. Almost nothing is reflected, again. At 150W with a couple of watts reflected, it's a no-brainer. However, if you are running a 50KW broadcast transmitter, reflected power greatly increases the transmitter's output amp heating problems so they are very careful with it. A 2:1 SWR means we have another 5000 watts of heat to cool off the finals, cooking them. The normally hot finals simply cook themselves. So a 3:1 swr with 6.25 watts of reflected power and 25 watts of forward power, still delivers 25 watts to the antenna to be radiated. That is of course when there is no feed line loss. Too bad this isn't true. If the final amp were purely reactive, it would be, but then there would be no match between the transmitter and feed line to begin with so there'd be no power output if it were purely reactive. With feed line loss involved (as there always is) you will get a false SWR reading. The more loss your cable has the better your SWR will look. Finally something that is true. SWR should be measured at the antenna if the line is long and lossy. However, this isn't that important in a boat with 50' of RG-58 at VHF. 73 de Larry W 4 C S C h h o a i a u r s r t o k l h l e e i y s n t a o n NNNN Larry W4CSC NNNN |
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#8
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How to use a simple SWR meter and what it means to your VHF
No, you just need to read the ones that you have. :)
See if you can find in any of them where it tells you that reflected power gets dissipated in the finals of the transmitter. I don't think you will. Regards Gary On Fri, 21 Nov 2003 17:25:33 -0500, "Doug Dotson" wrote: Humm. I guess I need to contact the ARRL and make arrangements to return all the Antenna Handbooks and Radio Amateur Handbooks I've accumulated over the past 30 years. Doug, k3qt s/v Callista "Gary Schafer" wrote in message .. . You need to tune your tuner only to provide the proper impedance match to your transmitter. A 50 ohm SWR bridge at the transmitter will tell you when you have achieved that. Swr on the feed line matters very little. SWR at the fixed 50 ohm output port of your transmitter matters allot. The networks inside your transmitter that provide the impedance match between your final amplifiers and the 50 ohm output port are fixed. They are not adjustable to match any other load. If you do not provide the proper 50 ohm load to the transmitter then the finals can draw excessive current and damage them. At the same time you may not have the proper impedance match to the finals that allow the transmitter to put out its designed power. As long as the transmitter with its fixed 50 ohm output sees a 50 ohm load it is happy. It doesn't matter what is happening in the feed line. If you have an antenna and a feed line that has a 3:1 SWR on it at the transmitter end the transmitter will not perform properly. If you place a matching device (tuner) between the transmitter and that feed line and tune it so that the transmitter sees a pure 50 ohms, then the transmitter is completely happy. But the feed line still has that same 3:1 SWR on it. 25% reflected power from the antenna. Place your SWR bridge between the tuner and the feed line and you will see it. Does that mean that 25% of the power is wasted? Where does it go? We just adjusted the tuner so that there was no SWR on the transmitter so it isn't going there. Put a watt meter at the antenna end of the feed line and guess what? You will see the full transmitter power there. Providing of course you don't have a high loss coax line. If the SWR on a coax line gets too high then there are going to be more cable losses due to excessive currents in the line. That is why open wire feed line has much less loss than coax. Because its impedance is higher the current is less for a given amount of power and you have less IR loss. RG 8 cable has less loss than RG 58. The RG 8 has bigger conductors so less resistance. If you use a cable with larger conductors or one with a higher impedance you will have less loss. As I mentioned before, with open wire line you can feed a dipole antenna on many bands and have very high SWR on the fed line and have negligible loss on the feed line. Look in your hand book on multi band antennas fed with open wire line. I keep mentioning open wire line only because it serves as a good example of systems often used with high SWR on the line with almost no loss. The same holds true for coax line but there is less written on it. And coax being a lower impedance will have higher currents and thus more inherent loss for a given amount of power. Regards Gary On Fri, 21 Nov 2003 09:18:38 -0500, "Doug Dotson" wrote: If SWR doesn't matter, then why do I need to tune my antenna or use an automatic tuner if all the reflectedd power eventually gets radiated? Why did my finals burn up when I keyed up into a very poorly mismatched antenna. Doug, k3qt s/v Callista "Larry W4CSC" wrote in message ... Ok, you go on believing that......... On Thu, 20 Nov 2003 18:02:21 GMT, Gary Schafer wrote: Simply not true?? You need to do some more reading Larry. A good start would be Walter Maxwell's book "reflections". It is explained there well. Even the later handbooks touch on the subject. First, impedance does not "absorb any reflected power". Reflected power on the antenna line DOES NOT go back into the final amplifier and get dissipated. That is an old wives tale that is probably older than all of us. The reason for "being careful" on a high power transmitter with reflected power is that the voltages can become very high due to the high impedance's involved in the tank circuit. Also circulating currents can become high in the matching components. Thus stressing the circuit components. But no great amount of reflected power is absorbed by anything. Ever look at the color of the plates on a high power transmitter working into a normal load verses a high SWR load? When tuned for the same power level in both cases there is no difference in plate color. If reflected power were being dissipated in the final plates they would be hotter, indicated by a hotter color. If you think that the tank coil in your 50 kw transmitter is going to dissipate 5 kw in heat,, then watch it glow red. But we both know it doesn't, right? With solid state amplifiers there is the problem of transistors not liking to work into complex impedance's. It causes them to draw very high currents. Nothing to do with absorbing reflected power. Have you ever used open wire feeders to an antenna? The SWR on the feed line can be very high. It can be in the order of 15 or 20:1 on the line depending on the antenna type and frequency being used. But there is almost no additional loss on the line over the line being 1:1. What do you think happens to all that reflected power on that feed line? Where do you think it gets dissipated? Hint, it all gets radiated. Regards Gary On Thu, 20 Nov 2003 12:38:22 GMT, (Larry W4CSC) wrote: On Thu, 20 Nov 2003 03:50:41 GMT, Gary Schafer wrote: SWR in itself is not necessarily bad. Power reflected back toward the transmitter is not lost as a result of the reflection itself. When that reflected power hits the transmitter it is re-reflected back up to the antenna. Simply not true. The source impedance of the output power amplifier is, ideally 50 ohms to match the cable. This impedance absorbs reflected power, converting it into heat in its resistive component which is lost. The output matching network of the transmitter is tuned to make it look resistive. Almost nothing is reflected, again. At 150W with a couple of watts reflected, it's a no-brainer. However, if you are running a 50KW broadcast transmitter, reflected power greatly increases the transmitter's output amp heating problems so they are very careful with it. A 2:1 SWR means we have another 5000 watts of heat to cool off the finals, cooking them. The normally hot finals simply cook themselves. So a 3:1 swr with 6.25 watts of reflected power and 25 watts of forward power, still delivers 25 watts to the antenna to be radiated. That is of course when there is no feed line loss. Too bad this isn't true. If the final amp were purely reactive, it would be, but then there would be no match between the transmitter and feed line to begin with so there'd be no power output if it were purely reactive. With feed line loss involved (as there always is) you will get a false SWR reading. The more loss your cable has the better your SWR will look. Finally something that is true. SWR should be measured at the antenna if the line is long and lossy. However, this isn't that important in a boat with 50' of RG-58 at VHF. 73 de Larry W 4 C S C h h o a i a u r s r t o k l h l e e i y s n t a o n NNNN Larry W4CSC NNNN |
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How to use a simple SWR meter and what it means to your VHF
"Gary Schafer" wrote in message
... No, you just need to read the ones that you have. :) See if you can find in any of them where it tells you that reflected power gets dissipated in the finals of the transmitter. I don't think you will. On page 10.1 of my VHF-UHF manual by G.R. Jessop it says: "a certain amount of power is reflected at this mis-termination [the antenna] and is propagated back down the line again by means of further waves of voltage and current travelling in the opposite direction, to be either absorbed or re-reflected at the generator according to whether the generator terminates or mis-terminated the line." Meindert |
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How to use a simple SWR meter and what it means to your VHF
On Fri, 21 Nov 2003 18:32:56 GMT, Gary Schafer
wrote: You need to tune your tuner only to provide the proper impedance match to your transmitter. A 50 ohm SWR bridge at the transmitter will tell you when you have achieved that. WHOA! There you go again! If I tune my transmitter to 50 ohms RESISTIVE, non-reactive, it will ABSORB any reflected power because it's acting like a RESISTOR, as it should, converting reflected power into HEAT in the final amp.....(c; Larry W4CSC NNNN |
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