[HBR] HBR-16 Front End Experiment
LeeCraner at aol.com
LeeCraner at aol.com
Mon Nov 23 15:29:38 EST 2009
Recently, I did some experimenting with the front end of my HBR-16, and
came up with some interesting results. I thought the reflector group might
be interested.
Summary Results:
After replacing the typical three terminal (antenna/antenna/ground) screw
type antenna connection on my HBR-16 with a coax connector, and then feeding
the primary of the HBR-16's input coil, L1 directly with RG58 coax, the
band to band variation in the receiver's input impedance was substantially
reduced. The resulting input impedance, by band, before and after the
modification was:
80 94 ohms (was 94 ohms)
40 75 ohms (was 75 ohms)
20 84 ohms (was 33 ohms)
15 68 ohms (was 27 ohms)
10 (see text)
My receiver:
My HBR-16 front end was constructed per Ted Crosby's original design.
That is, the input coil L1 is mounted close to the front panel and the antenna
terminal is a ceramic three screw terminal on the back of the chassis.
The primary of L1 is connected to two of the antenna terminal screws through
two coax cables giving the HBR-16 a balanced input. The coils were wound
according to Ted's article.
In typical modern fashion, I use unbalanced 50 ohm coax from the receiver
to the antenna. So the center of the coax is connected to one of the
antenna terminal screws, the shield is connected to the other antenna terminal
screws and a jumper connects this screw to ground.
Object:
It has been suggested that a 300-75 ohm TV balun improves many older
receivers that have a Hi-Z balanced antenna connection, such as the 75A Collins
receiver, when connected to a coax fed antenna. The original object was to
calculate the input impedance of my HBR-16 to determine whether such a
balun, connecting my unbalanced 50 ohm antenna to the balanced HBR-16 L1
primary would be worthwhile. In other words, if the HBR-16's had a Hi-Z antenna
input impedance at the antenna terminals (200 ohms or more), a 4:1 balun,
matching the unbalanced 50 ohm antenna to the balanced L1 primary, might be
worthwhile.
Equipment Used:
URM-25D RF signal generator (the URM-25D has a 50 ohm unbalanced output)
CN-224 50 ohm 20 dB (10:1 voltage) pi attenuator
MX-1487 50 ohm termination (aka "impedance adapter")
Tektronix 465 two channel ooscilloscope
Theory:
By comparing the RF voltages at the input (Vi) and output (Vo) of an
attenuator between an RF generator and an unknown impedance, the unknown
impedance, Z, can be calculated using:
Z=(15,225Vo)/(61.1Vi-308.6Vo)
Where 61.1 ohms is the input and output shunt resistors of the attenuator,
247.5 ohms is the attenuator's series resistor, 15,225 is the product or
61.1 x 247.5 and 308.6 is the sum of 61.1 + 247.5.
Test setup:
In order to measure the input and output RF voltages at the attenuator,
coax tee fittings were connected at each end of the attenuator and the output
of the two tee fittings were connected to the two channels of the scope.
The output of the signal generator was then first connected through the 20
dB attenuator to the 50 ohm termination and measurements taken in the
middle of the five primary ham bands. At 80, 40, 20 and 15 meters the output
voltage at the attenuator was exactly 1/10 (-20dB) of the input voltage,
thus validating that the setup was correctly seeing the 50 ohm termination
impedance on these bands. However, at 10 meters, the output voltage was about
1/20 the input voltage, thus invalidating any results on 10 meters
(probably due to length of the connecting cables, etc.). Since I don't use my
HBR-16 on 10, I confined any further testing to 80-15 meters.
The 50 ohm termination was removed and the attenuator hooked up to the
HBR-16's antenna input terminals. Measurements in the middle of the 80-15
bands were again taken and the HBR-16's impedance at each band calculated from
the input and output RF voltages.
The results, by band, were:
80 94 ohms
40 75 ohms
20 33 ohms
15 27 ohms
With these Lo-Z results, it appeared that a 4:1 balun (the original reason
for the experiment) wouldn't help match a 50 ohm antenna to the HBR-16 and
that a direct 50 ohm connection at the L1 primary might be a better route.
So I removed the three terminal antenna block and the two coax cables
connecting it to L1's primary. In its place, I mounted a BNC jack to the
receiver's rear chassis and connected it directly to one side of the L1 primary
through a length of RG58 coax. The other side of L1's primary was
grounded at the L1 socket (in Ted's original configuration this would have been
grounded at the rear chassis when using an unbalanced antenna). Remeasuring
the impedances at each band at the newly installed BNC connector resulted
in:
80 94 ohms
40 75 ohms
20 84 ohms
15 68 ohms
Conclusions:
It would appear that the original balanced configuration with two coax
cables between L1 and the antenna connector significantly affected the
impedances on 20 and 15, and that bringing the 50 ohm unbalance line all the way
to L1 had some benefit. Though no results were calculated at 10 meters, it
probably benefited from the modification as well.
A question remains whether the modification resulted in any practical
improvement in performance. Unfortunately, I didn't measure the sensitivity of
the receiver before the modification. I did a quick sensitivity
measurement on 40 meters after the modification (40 meters being the coil set that
happended to be installed at the time) and got a 0.32 uv 10dB S+N/N figure.
Not bad for a 50 year old homebrew receiver design.
If anyone would like a copy of the Excel spreadsheet I used to make the
impedance calculations, drop me an email.
73
Lee WB6SSW
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