Difference between revisions of "UHF Exciter"
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# once this is verified, it's time to align the exciter. This writes the data in to the exciter CPU internal EEPROM. | # once this is verified, it's time to align the exciter. This writes the data in to the exciter CPU internal EEPROM. | ||
The deviation and linearity need to be aligned. The exciter will calibrate the deviation of every mode once the exciter is setup. Note the frequencies used, you're aligning the minimum and maximum of each VCO. | The deviation and linearity need to be aligned. The exciter will calibrate the deviation of every mode once the exciter is setup. Note the frequencies used, you're aligning the minimum and maximum of each VCO. | ||
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Revision as of 21:49, 30 November 2016
Technically this is correct. Formatting and layout needs to be cleaned up
The UHF R1-R4 exciter are based on a common design. UHF R0 is a newer design covering 380-433 MHz.
Exciter
- Test it first! Trying to modify a broken exciter is like pushing a rope.
- Remove the board from the case and take off the covers.
- Now locate the VCOs (IC3200). These are sealed units and have no diagram. Check out the schematic! The Diagram is wrong when it shows the upper and lower VCO!
- 4 Looking at the VCO I find it's easier to remove the copper shield than try to desolder the entire VCO module.
The VCO substrate is ceramic high K board. It's sensitive to thermal shock, so be careful about this, as it will crack. It's sicking noise. The best way to remove the VCO shield is using chip quick on the "pins" under the board and then flipping it over and using a preheater on the underside for 3-4 min at 450°f.
Prior to preheating I fashion supports out of Aluminum foil or other material and jam them between the PCB and the underside of the VCO. This will prevent the VCO board from falling off it's pins when removing the shield. Once this is done, mask off the area using hole cut in some foil. This is a heat shield for the other parts of the board.
Now turn on the preheater and wait for the board to warm up. Once it's up to 450° F take a hot air wand set to 15 l/min of flow and 650°f to the shield. After about 2-3 min it will loosen and you can pull the shield straight up. Careful you don't disturb any of the VCO parts, as they will most likely be reflowed too. If you do, don't panic, just look at the before picture and put everything back to how it was on the VCO. It's a pretty easy circuit to figure out.
Once you have the VCO exposed you can attach test wires to it. You'll need the following points
- 8.5 V power to high and low VCO (not at the same time, just tack the wire on)
- 0-12 V on the steering line
- output loops of wire on the VCO output. These are to be looped around a probe and into a spectrum anaylizer to view the output.
First a couple things about the VCO's,
- with the shield on they move up about 2.5 MHz
- from hot to cold Fr changes about 1.5 to 2 MHz. Hotter makes Fr go down, cool makes it go up.
- removing capacitance makes Fr go up.
- removing inductance makes Fr go up.
- the sweet spot for the VCO steering voltage os 2.5-7.5 v
- each VCO is designed to cover half the range of the quantar.
- * The Exciter will change VCO's when it hits it's center frequency +25khz. You can verify this my looking at the steering voltage in the exciter as you change frequencies. A test config file (Codeplug) makes this easy.
Starting with the low VCO, hook it up and sweep the 0-12v supply to check it's 385-430 MHz. within 5 MHz is ok, this VCO only covers 16 MHz in operation.
- put 5.5v on the steering line.
We're going to align it for a CF of 444 MHz. The reason for this is the lower VCO covers 438-454, making the center 446, but with the shield off we will see the CF be ~2 MHz lower. The shield adds capacitance to the circuit and this ups the resonte frequency.
With the voltage on the steering line, cut a 75 mill strip of .250 copper foil. It's not critical, you'll be adjusting it. Place it on the VCO Trombone to short out part of the stripline. You can safely monitor the output of the VCO and move this at the same time. I've found it's best to shoot lower than 444 MHz. Once you are within a few MHz, let the board cool. You'll find the Fr rising as it cools. Moving the short closer to the trombone end lowers Fr, pulling it further away from the end raises Fr.
- now while monitoring the VCO output on the spectrum anyliser, use a dimond tip dremmel grinder and remove some of the high impediance end tuning cap on the vco. Go a very little at a time, it makes a big difference. Use this to bring the VCO frequency up to 444 MHz on the dot. It's normal for the VCO to jump a couple hundred KHZ or so depending on the stability of your power supply. There is no PLL running to lock it.
- now lets test the VCO with the cover off you should see the following (give or take a few MHZ). Keep in mind with the shield in place you'll see the frequency go up about 2 MHz.
Voltage | Low | High |
---|---|---|
.8 | 425 | 442 |
5.5 | 444 | 460 |
9.2 | 461 | 477 |
The VCO is most happy running at 2.5 to 7.5 volts, and needs to cover 438-454 and 454-470. So long as it covers this range in between 2.5 to 7.5 Volts it will work. there is a bit more space on the low end than the high end, so if it runs at 2v at for 438 vs 2.5v for 438 MHz, it's not a concern. Keep in mind the Fr is lower with the cover off, so if it's 1v at 438 while tuning it, there is a good chance it will not lock with the case on.
- After the Lower VCO is modified, modify the high one.
Remove the 8.5v from the Low VCO and put it on the high VCO line and hook up your spectrum analyzer on the output. Verify the existing tuning range of 406-440 from 0 to 10v. It's normal to see spurs near the 0 and 12v steering levels.
Once it's working correctly and you see the upper VCO, you need to do the same procedure as the low vco.
With 5.5v on the steering line, and add a .075 with copper strip on the trombone side of the VCO tank. We need to align this to a bit lower (.5 to 1 MHz) than center frequency of 460 (again we're expecting this to be 462 MHz with the cover on the VCO). This allows us to peek the VCO right onto 460 MHz by trimming up the capacitor with a Dremel.
Allow the VCO to cool and verify the high tuning range between 2.5 and 7.5 of 452-468 (454-470 with case on). Again it's not critical, but we need to have this be in the center of the total VCO range to keep things linear.
- Change the Exciter Modulation input
The Quantar has a splatter filter on the modulation input on the VCO's. What we've done makes the VCO a bit more sensitive to modulation input and while the Quantar can calibrate up to a 10khz deviation on the test level, in some cases we see >10khz of deviation. The soultion to this is a resistor change in the voltage divider of R3250/R3251.
- Changing R3250 from 10k to 16k seams to reliably resolve this. It's a 5% 0805 size part, and very easy to work with.
- Change the exciter ID.
As you can see in the Table above, we need the change the ID from R1 to R2. This is a simple 1 resistor move.
- Move R3700 to R3701
- additional changes
Technically two more parts need to be changed, C3112 and C3277 need to be changed from 3.3 to 2.7 pF. I've not changed these and found all output to be right on the money. You're welcome to change them if you have 0805 size 2.7 pF caps on hand.
Once this is all done, it's time to put the VCO shield back on.
- make sure you clean up the VCO PCB with flux remover first.
- ensure you have all the Chipquick removed from the bottom holes in the PCB.
- Solder the PCB holes in place first
- use a small tip to solder the shield back on the VCO.
- You can verify the tuning range once again if you so choose. In alignment I test the exciter with a test code plug and use the built in volt meter to monitor it.
Now reassemble the entire PCB in the chassis and put the shields back in place. It's a good time to upgrade the firmware too.
- Put the exciter back in the chassis and hook it up to the PA. For the first part of this testing we will only look at the steering voltage of the VCO as reported in the RSS. We don't need to engage the transmitter as the VCO will run all the time the exciter is on.
- Setup a test code plug with the following in it.
Channel | Frequency | Voltage |
---|---|---|
1. | 420.00 | |
2. | 425.00 | |
3. | 430.00 | |
4. | 435.00 | |
5. | 438.00 | 2.5 |
6. | 454.00 | 7.0 |
7. | 454.25 | 2.5 |
8. | 470.00 | 7.0 |
9. | 475.00 | |
10. | 480.00 | |
11. | 485.00 | |
12. | 490.00 | |
13. | 495.00 | |
14. | 500.00 |
Check that the switch over happens at 454.25 MHz. Again you want the voltages to be as close as possible, but even a volt off is not a huge deal so long as you're over 1v and under 8v for the maximum and minimum.
- once this is verified, it's time to align the exciter. This writes the data in to the exciter CPU internal EEPROM.
The deviation and linearity need to be aligned. The exciter will calibrate the deviation of every mode once the exciter is setup. Note the frequencies used, you're aligning the minimum and maximum of each VCO.