MITEL MT3371BS, MT3371BN, MT3370BN, MT3370BS, MT3271BE Datasheet

The SL1461SA is a wideband PLL FM demodulator,

intended primarily for application in satellite tuners.

The device contains all elements necessary, with the
exception of external oscillator sustaining network and loop
feedback components, to form a complete PLL system
operating at frequencies up to 800MHz.

An AFC with window adjust is provided, whose output
signal can be used to correct for any frequency drift at the head
end local oscillator.

FEATURES

■ Single chip PLL system for wideband FM

demodulation

■ Simple low component count application

■ Allows for application of threshold extension

■ Fully balanced low radiation design

■ High operating input sensivity

■ Improved VCO stability with variations in supply or

temperature

■ AGC detect and bias adjust

■ 75Ω video output drive with low distortion levels

■ Dynamic self biasing analog AFC

■ Full ESD Protection*

* Normal ESD handling procedures should be observed

Wideband PLL FM Demodulator

Advance Information

DS4049 - 1.2 December 1994

AFC PUMP

AFC WINDOW ADJUST

EE

V
OSCILLATOR +
OSCILLATOR –

AGC BIAS

AGC OUTPUT

RF INPUT

Fig.1 Pin connections - top view

APPLICATIONS

■ Satellite receiver systems

■ Data communications Systems

ORDERING INFORMATION

SL1461SA/KG/MPAS

16116

2

15

3

14

4

13

5

12

SL1461SA

6

11
10

7
89

SL1461SA

AFC OUTPUT

V

CC

VIDEO FEEDBACK +
VIDEO –

VIDEO +
VIDEO FEEDBACK –
VIDEO OUTPUT

RF INPUT

MP16

AGC BIAS

RF INPUTS

AGC OUTPUT

LOCAL

OSCILLATOR

AFC WINDOW

ADJUST

6

8
9

7

4
5

2

14

VIDEO
FEEDBACK +

12

VIDEO +

13

VIDEO –

11

VIDEO
FEEDBACK –

10

VIDEO
OUTPUT

1

AFC PUMP

16

AFC OUTPUT

Fig.2 SL1461SA block diagram

SL1461SA

ELECTRICAL CHARACTERISTICS

T

= -20°C to +80°C, VCC = +4.5V to +5.5V. The electrical characteristics are guaranteed by either production test or design.

amb

They apply within the specified ambient temperature and supply voltage unless otherwise stated.

Characteristics

Supply current
Operating frequency
Input sensitivity
Input overload
VCO sensitivity (dF/dV)
VCO linearity

VCO supply stability
VCO temperature stability
Phase detector gain

Loop amplifier input impedance
Loop amplifier output impedance
Loop amplifier open loop gain
Loop amplifier gain bandwidth product
Loop amplifier output swing
Video drive output impedance
Video drive:
Luminance nonlinearity

- differential gain

- differential phase

- intermodulation

- signal/noise

- Tilt

- baseline distortion
AGC output current
AGC bias current
AFC window current
AFC charge pump current
AFC leakage current
AFC output saturation voltage

Value

Min. Typ. Max.

36

300

40

800

-40

0

25

32

39

25

2.0
20

0.5

0.25

450

570

700
25
38

240

1.2

55

75

1.9

0.5

1.0

95

5

2.5
3

-40

66

10

0
0

72

0.3

0.4

3
2

400
250
400

50

10

0.4

Units

mA
MHz
dBm
dBm

MHz/V

%

MHz/V

KHz/°C

V/rad
V/rad

Ω
Ω

dB
MHz
Vp-p

Ω

%
%

Degree

dB

dB

%
%

µA

µA

µA

µA

µA

V

Conditions

Preamp limiting

Refer to application in Fig. 3
Refer to application in Fig. 3; with

13.5MHz p-p deviation
See note 5
See note 5
Differential loop filter
Single ended loop filter
Single ended
Single ended
Single ended
Single ended
Single ended

1KΩ load, See note 3 and 4
75KΩ load, See note 3 and 4
75KΩ load, See note 3 and 4
See notes 1, 3 and 4
1KΩ load, See note 2 and 4
1KΩ load, See note 3 and 4
1KΩ load, See note 3 and 4
Maximum load voltage drop 2V

400µA gives 1.5V deadband window

With charge pump disabled
AFC output enabled

Note 1. Product of input modulation f 1 at 4.43MHz, 13.5MHz p–p deviation and f 2 at 6MHz p–p deviation, (PAL chroma and sound

subcarriers).

Note 2. Ratio of output video signal with input modulation at 1MHz, 13.5MHz p–p deviation, to output rms noise in 6MHz bandwidth with

no input modulation.
Note 3. Input test signal pre–emphasised video 13.5MHz p–p deviation. Output voltage 600mV pk–pk.
Note 4. See page 3
Note 5. Assuming operating frequency of 479.5MHz set with V

shown in Fig. 3. also refer to Fig. 8.

@ 5.0V and ambient temperature of +20°C. Only applies to Application

CC

2

SL1461SA

TEST CONFIGURATION

VIDEO GENERATOR

ROHDE & SCHWARZ SGPF

PRE EMPHASISED BASE BAND VIDEO

DE EMPHASISED BASE BAND VIDEO 1V p–p

The video drive characteristics measurements were made using the above test configuration. The maximum figures recorded in
the Electrical Characteristics Table coincide with high temperatures and extremes of supply voltage. No adjustment to the recorded
figures has been made to compensate for the effects of temperature on the external components of the application test board, in
particular the varactor diodes. If operation of the device at high ambient temperatures is envisaged then attention to temperature
compensation of the external circuitry will result in performance figures closer to the stated typical figures.

BASE BAND VIDEO 1V p–p

ROHDE & SCHWARZ SFZ

RF CARRIER FREQ 479.5MHz

FM MODULATION 13.5MHz P–P

PRE–EMPHASISED VIDEO

MONTFORD
TEST OVEN

SL1461 TEST APPLICATION BOARD

See Fig. 3 for details

DE EMPHASISED NETWORK

ROHDE & SCHWARZ UAF

TV SAT TEST TX

VIDEO AMPLIFIER/

VIDEO ANAL YSER

ABSOLUTE MAXIMUM RATINGS

All voltages are referred to VEE at 0V

Characteristics

Supply voltage
RF input voltage
RF input DC offset
Oscillator ± DC offset
Video ± DC offset
Video feedback ± DC offset
Video output DC offset
AFC pump DC offset
AFC disable DC offset
AFC deadband DC offset
AGC bias DC offset
AGC output DC offset
Storage temperature
Junction temperature
MP16 package thermal resistance,

chip to ambient

Fig.2 SL1461SA block diagram

Min. Typ. Max.

-0.3

-0.3

-0.3

-0.3

-0.3

-0.3

-0.3

-0.3

-0.3

-0.3

-0.3

-55

7

2.5

V

+0.3

CC

V

+0.3

CC

V

+0.3

CC

VCC+0.3
V

+0.3

CC

V

+0.3

CC

V

+0.3

CC

VCC+0.3
V

+0.3

CC

V

+0.3

CC

125
150
111

V

Vp-p

V
V
V
V
V
V
V
V
V
V

°C
°C

°C/W

Conditions

3

SL1461SA

ABSOLUTE MAXIMUM RATINGS cont.

All voltages are referred to V

Characteristics

EE

at 0V

Min. Typ. Max.

Conditions

MP16 package thermal resistance,
chip to case

Power consumption at 5.5V
ESD protection - pins 1 to 15
ESD protection - Pin 16

2K

AGC BIAS AFC WINDOW ADJUST

RV1 RV2

D1

BB515
BB515

D2

C5

470nF

TP3

4n7

C6

2

1.7

50K

47nF 100nF

R1

4K7

R2

5K1

R3

4K7

41

250

1nF

°C/W

mW

kV
kV

27K

C2C1

16116

2

15

3

14

4

13

5

12

SL1461SA

6

11
10

7
89

C8C7

Mil-std-883 method 3015 class 1
Mil-std-883 method 3015 class 1

R6

R5

1K2

R4

1K2

1nF

TP4

C9

100pF

47

100nF

C11

C10

F

C3

TP1

TP2

100pF

F

47

C4

VIDEO OUTPUT

+5V

1nF

C12

RF INPUT

Fig.3 Standard application circuit

FUNCTIONAL DESCRIPTION

The SL1461SA is a wideband PLL FM demodulator,
optimised for application in satellite receiver systems and
requiring a minimum external component count. It contains all
the elements required for construction of a phase locked loop
circuit, with the exception of tuning components for the local
oscillator, and an AFC detector circuit for generation of error
signal to correct for any frequency drift in the outdoor unit local
oscillator. A block diagram is contained in Fig. 2 and the typical
application in Fig. 3.

The internal pin connections are contained in Fig.6/6a

In normal applications the second satellite IF frequency of
typically 402 or 479.5MHz is fed to the RF preamplifier, which
has a working sensitivity of typically -40 dBm, depending on
application and layout. The preamplifier contains an RF level
detect circuit, which generates an AGC signal that can be used
for controlling the gain of the IF amplifier stages, so maintaining
a fixed level to the RF input of the SL1461SA, for optimum
threshold performance. The bias point of the AGC circuit can
be adjusted to cater for variation in AGC line voltage
requirement and device input power. The typical AGC curves
are shown in Fig. 9. It is recommended that the device is
operated with an input signal between -30 and -35dBm. This

ensures optimum linearity and threshold performance, and
gives a good safety margin over the typical sensitivity of

-40dBm.
The output of the preamplifier is fed to the mixer section

which is of balanced design for low radiation. In this stage the
RF signal is mixed with the local oscillator frequency, which is
generatedby an on–board oscillator. The oscillator block uses
an external varactor tuned sustaining network and is optimised
for high linearity over the normal deviation range. A typical
frequency versus voltage characteristic for the oscillator is
contained in Fig. 7. The loop output is designed to compensate
for first order temperature variation effects; the typical stability
is shown in Fig. 8

The output of the mixer is then fed to the loop amplifier

around which feedback is applied to determine loop transfer
characteristic . Feedback can be applied either in differential or
single ended mode; if the appropriate phase detector gains are
assumed in calculating loop filters, both modes should give the
same loop response.

The loop amplifier drives a 75Ω output impedance buffer

amplifier, which can either be connected to a 75Ω load or used
to drive a high input impedance stage giving greater linearity
and approximately 6dB higher demodulated signal output
level.

4