Communication Concepts AN779 Application Note User Manual

AR

C

HIVE INF

O

RMA

TI

O

N

PRODUCT TRANSFERRED T

O

M/A

–

COM

AN779

4

RF Application Reports

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

X

= Feedthrough Eyelets.

= Terminal Pins

R9

Q1

Q2

Q3

Q4

R8

R1
0

R11

C9

C8

R6

C10

C7

C6

RFC4

RFC3

B

B

B

B

C11

C1
2

C1
4

R12

C1
3

RFC5

D2

R7

Beads

Beads

D1

R3

R4

C3

RFC2

R5

C5

C4

RFC1

C2

R1

R2

Figure 5. Component Layout Diagram of Low-Cost 20 W Amplifier

The leads of R7 and R12 form the one-turn feedback windings in T2

and T3. Ferrite beads in dc line can be seen located under T1 and T2.

The input impedance of the MRF476 is 7.55, –j0.65 ohms

at 30 MHz resulting in the base-to-base impedance of

2 x (7.55

2

+ 0.65

2

) = 15.2 ohms.

This, in series with networks R1, C1 and R4, C3 (2 x 4.4
ohms), gives 24 ohms, and would require a 2:1 impedance
ratio transformer for a 50-ohm interface. However, due to the
influence of strong negative feedback in this stage, a better
overall matching is possible with 4:1 ratio. The input net-
works were designed in a manner similar to that described in
Reference 8.

Measurements and Performance Data

At a power output of 20 W CW, all output harmonics were

measured about 30 dB or more below the fundamental,
except for the third harmonic which was only attenuated 17
dB to 18 dB at frequencies below 5 MHz. Typical numbers
for the higher order distortion products (d9 and d11) are in
the order of – 60 dB above 7 MHz and – 50 dB to – 55 dB
at the lower frequencies. These both can be substantially
reduced by increasing the idle currents, but larger heat sinks

would be necessary to accommodate the increased
dissipation.

The efficiency shown in Figures 6 and 7 represents the

overall figure for both stages. Currents through the bias
networks, which are 82/(13.6 – 0.7) = 0.16 A each, are
excluded. Modified values for R5 and R6 may have to be
selected, depending on the forward voltage characteristics
of D1 and D2.

Although this amplifier was designed to serve as a 1.6

to 30 MHz broadband driver, it is suitable for the citizens
band use as well. With some modifications and design
shortcuts, the optimization can be concentrated to one
frequency.

POWER GAIN (dB)

IMD (dB)

30
29
28
27
26

35

40

45

V

CC

= 13.6 V P

out

= 20 W PEP

d

5

d

3

G

PE

Figure 6. Intermodulation Distortion and Power Gain

versus Frequency