MITEL SL2035MP1S, SL2035MP1T, SL2035, SL2035IG Datasheet

DS5117 Issue 2.1 October 1999

SL2035

High Performance Broadband Downconverter

Preliminary Information

Ordering Information

SL2035/IG/MP1S (Tubes)
SL2035/IG/MP1T (Tape and Reel)

Features

● Single Chip Broadband Solution

● Wide Dynamic Range RF Input

● Low Phase Noise Balanced Internal Local Oscillator

● High Frequency Range: 1 to 1·3 GHz

● ESD Protection 2kV min., MIL-STD-883B Method 3015

Cat.1 (Normal ESD handling procedures should be
observed)

Applications

● Double Conversion Tuners

● Digital Terrestrial Tuners

● Data Transmit Systems

● Data Communications Systems

The SL2035 is a bipolar, broadband wide dynamic range
mixer oscillator, optimised for applications as the
downconverter in double conversion tuner systems. It also
has application in any system where a wide dynamic range
broadband frequency converter is required.

The SL2035 is a single chip containing all necessary active
circuitry and simply requires an external tuneable resonant
network for the local oscillator. The block diagram is shown
in Figure 1 and pin connections are shown in Figure 2.

In normal application the signal from the high IF output is
connected to the RFIN and RFIN inputs. The RF input
preamplifier of the device is designed for low noise figure
within the operating region and for high intermodulation
distortion intercept so offering good signal to noise plus
composite distortion spurious performance.

The preamplifier also provides gain to the mixer section
and back isolation from the local oscillator section. The
approximate model of the RF input is shown in Figure 3.

Absolute Maximum Ratings

Supply voltage, V

CC

RF differential input voltage
All I/O port DC offset
Storage temperature
Junction temperature
Package thermal resistance

Chip to ambient, θ

JA

Chip to case, θ

JC

20·3V to 17V

2·5V

20·3 to VCC 10·3V

255°C to 1150°C

1150°C

20°C/W
80°C/W

The output of the preamplifier is fed to the mixer section
which is optimised for low radiation application. In this stage
the RF signal is mixed with the local oscillator frequency,
which is generated by an on-chip oscillator. The oscillator
block uses an external tuneable network and is optimised
for low phase noise. A typical application is shown in
Figure 5. This block also contains a buffer-amplifier to
interface with an external PLL to allow for frequency
synthesis of the local oscillator.

The IF output can be loaded either differentially or single­ended. It is recommended that the differential load as in
Figure 5 is applied as this gives best noise performance. If
the output is loaded single-ended the noise figure will be
degraded. The approximate model of the IF output is shown
in Figure 4.

In application care should be taken to achieve symmetric
balance to the IF outputs to maximise intermodulation
performance.

Figure 1 SL2035 block diagram

RFIN

RFIN

LO2

LO1

IF1

IF2

PRSC1

2

SL2035

Figure 2 Pin connections - top view

Quick Reference Data

All data applies with circuit component values given in Table 1

Characteristic

Value Units

MP16

SL

2035

1

2

3

4

5

6

7

8

16

15

14

13

12

11

10

9

IF2

NC

GND

GND

GND

GND

RFIN

RFIN

IF1

NC

V

CC

/VCO

LO2

LO1

V

CC

/VCO

PRSC1

VCC/LNA

Electrical Characteristics

Tamb = 240°C to 185°C, VCC = 5V 65%, VEE = 0V. These characteristics are guaranteed by either production test or
design. They apply within the specified ambient temperature and supply voltage ranges unless otherwise stated.

Characteristic Conditions

Max.

Min.

Value

Typ.

Units

IF output pins 1 and 16 will be nominally
connected to VCC through the differential
balun load as in Figure 5

Operating condition only
See Figure 3
See Note 1
T

AMB

= 27°C, with input matching network
as in Figure 5.
With differential load
Differential voltage gain to 50Ω load on
output of impedance transformer as in
Figure 5
Channel bandwidth 8MHz within operating
frequency range
995-1305MHz
See Note 1
Application as Figure 5. See Note 2
Application as Figure 5
Application as Figure 5
Compatible with all standard IF frequencies,
determined by application

Pin

99

1300

221

13

12
14

0·5

220

125

1·4
288
TBA

60

9,11,14

7,8
7,8
7,8
7,8

12,13

1,16

1000

27

9

8

116

0·9

295

30

97

10

11

118

290

mA

MHz

dBµV

dB
dB

dB

dB

dB

dBµV

GHz
dBc/Hz
dBc/Hz

MHz

Supply current

Input frequency range
Composite peak input signal
Input impedance
Input return loss
Input noise figure

Conversion gain

Gain variation within channel

Through gain
IIP3
LO operating range
LO phase noise, 10kHz offset
LO phase noise floor
IF output frequency range

cont…

NOTES

1. Any two tones within RF operating range at 92dBµV with output load as in Figure 5.

2. Use low side LO injection.

RF input operating frequency range
Input noise Figure, SSB
Conversion gain
IIP3 input referred
P1dB input referred
LO phase noise at 10 kHz offset, fRF 1 to 1·3GHz, application as in Figure 5

1000-1300

12

11
118
106

,290

MHz

dB
dB

dBµV

dBc

dBc/Hz