Theory of operation, Ȧȡ ȣ, Ȧȱ ȳ – Philips SA5205A User Manual

Philips Semiconductors

Product specification

SA5205A

Wide-band high-frequency amplifier

1997 Nov 07

7

THEORY OF OPERATION

The design is based on the use of multiple feedback loops to
provide wide-band gain together with good noise figure and terminal
impedance matches. Referring to the circuit schematic in Figure 17,
the gain is set primarily by the equation:

V

OUT

V

IN

+

ǒ

R

F1

)

R

E1

Ǔ

R

E1

(1)

which is series-shunt feedback. There is also shunt-series feedback
due to R

F2

and R

E2

which aids in producing wideband terminal

impedances without the need for low value input shunting resistors
that would degrade the noise figure. For optimum noise
performance, R

E1

and the base resistance of Q

1

are kept as low as

possible while R

F2

is maximized.

The noise figure is given by the following equation:

NF =

10 log

ȧ

ȡ
Ȣ

1

)

ȧ

ȱ

Ȳ

r

b

)

R

E1

)

KT

2ql

C1

R

O

ȧ

ȳ

ȴȧ

ȣ
Ȥ

dB

(2)

where I

C1

=5.5mA, R

E1

=12

Ω

, r

b

=130

Ω

, KT/q=26mV at 25

°

C and

R

0

=50 for a 50

Ω

system and 75 for a 75

Ω

system.

The DC input voltage level V

IN

can be determined by the equation:

V

IN

=V

BE1

+(I

C1

+I

C3

) R

E1

where R

E1

=12

Ω

, V

BE

=0.8V, I

C1

=5mA and I

C3

=7mA (currents rated

at V

CC

=6V).

Under the above conditions, V

IN

is approximately equal to 1V.

Level shifting is achieved by emitter-follower Q

3

and diode Q

4

which

provide shunt feedback to the emitter of Q

1

via R

F1

. The use of an

emitter-follower buffer in this feedback loop essentially eliminates
problems of shunt feedback loading on the output. The value of
R

F1

=140

Ω

is chosen to give the desired nominal gain. The DC

output voltage V

OUT

can be determined by:

V

OUT

=V

CC

-(I

C2

+I

C6

)R2,(4)

where V

CC

=6V, R

2

=225

Ω

, I

C2

=8mA and I

C6

=5mA.

From here it can be seen that the output voltage is approximately
3.1V to give relatively equal positive and negative output swings.
Diode Q

5

is included for bias purposes to allow direct coupling of

R

F2

to the base of Q

1

. The dual feedback loops stabilize the DC

operating point of the amplifier.

The output stage is a Darlington pair (Q

6

and Q

2

) which increases

the DC bias voltage on the input stage (Q

1

) to a more desirable

value, and also increases the feedback loop gain. Resistor R

0

optimizes the output VSWR (Voltage Standing Wave Ratio).
Inductors L

1

and L

2

are bondwire and lead inductances which are

roughly 3nH. These improve the high-frequency impedance
matches at input and output by partially resonating with 0.5pF of pad
and package capacitance.

V

IN

L2

3nH

Q1

Q4

RF1

140

RE1

12

RF2

200

Q5

RE2
12

R3
140

Q6

10

3nH

L2

V

OUT

R2

225

V

CC

R1

650

R0

Q3

Q2

SR00231

Figure 17. Schematic Diagram