Datasheet MC13135P, MC13136DW, MC13136P, MC13135DW Datasheet (Motorola)

Operating

Temperature Range




DUAL CONVERSION

NARROWBAND
FM RECEIVERS

ORDERING INFORMATION

P SUFFIX

PLASTIC PACKAGE

CASE 724

Order this document by MC13135/D

DW SUFFIX

PLASTIC PACKAGE

CASE 751E

(SO–24L)

24

1

24

1

Device Package

MC13135P
MC13135DW

TA = – 40° to +85°C

Plastic DIP

SO–24L
MC13136P
MC13136DW

Plastic DIP

SO–24L

1

MOTOROLA ANALOG IC DEVICE DATA

  

The MC13135/MC13136 are the second generation of single chip, dual
conversion FM communications receivers developed by Motorola. Major
improvements in signal handling, RSSI and first oscillator operation have
been made. In addition, recovered audio distortion and audio drive have
improved. Using Motorola’s MOSAIC 1.5 process, these receivers offer
low noise, high gain and stability over a wide operating voltage range.

Both the MC13135 and MC13136 include a Colpitts oscillator, VCO tuning
diode, low noise first and second mixer and LO, high gain limiting IF, and
RSSI. The MC13135 is designed for use with an LC quadrature detector and
has an uncommitted op amp that can be used either for an RSSI buffer or as
a data comparator. The MC13136 can be used with either a ceramic
discriminator or an LC quad coil and the op amp is internally connected for a
voltage buffered RSSI output.

These devices can be used as stand–alone VHF receivers or as the lower
IF of a triple conversion system. Applications include cordless telephones,
short range data links, walkie–talkies, low cost land mobile, amateur radio
receivers, baby monitors and scanners.

• Complete Dual Conversion FM Receiver – Antenna to Audio Output

• Input Frequency Range – 200 MHz

• Voltage Buffered RSSI with 70 dB of Usable Range

• Low Voltage Operation – 2.0 to 6.0 Vdc (2 Cell NiCad Supply)

• Low Current Drain – 3.5 mA Typ

• Low Impedance Audio Output < 25 Ω

• VHF Colpitts First LO for Crystal or VCO Operation

• Isolated Tuning Diode

• Buffered First LO Output to Drive CMOS PLL Synthesizer

23
22
21

20
19

18
17
16

15
14

13

12

11

10

9

8

7

6

5

4

3

2

1

24

AF

VCC2

2nd LO

VCC1

1st LO

Varicap

Limiter

Demod

1st LO Base

1st LO Emitter

1st LO Out

VCC1

2nd LO Emitter

2nd LO Base

2nd Mixer Out

V

EE

Limiter In
Decouple 1
Decouple 2

RSSI

Varicap C
Varicap A

1st Mixer In 1
1st Mixer In 2
1st Mixer Out

VCC2
2nd Mixer In

Audio Out
Op Amp Out
Op Amp In –
Op Amp In +

Quad Coil

23
22

21
20
19

18
17
16

15
14

13

12

11

10

9

8

7

6

5

4

3

2

1

24

AF

V

CC2

2nd LO

VCC1

1st LO

Varicap

Limiter

Demod

1st LO Base

1st LO Emitter

1st LO Out

VCC1

2nd LO Emitter

2nd LO Base

2nd Mixer Out

V

EE

Limiter In
Decouple 1
Decouple 2

RSSI

Varicap C
Varicap A

1st Mixer In 1
1st Mixer In 2

1st Mixer Out
VCC2
2nd Mixer In
Audio Out
Buffered RSSI Output
Op Amp In –
Limiter Output

Quad Input

MC13135 MC13136

PIN CONNECTIONS

Each device contains 142 active transistors.

 Motorola, Inc. 1996 Rev 3

MC13135 MC13136

2

MOTOROLA ANALOG IC DEVICE DATA

MAXIMUM RATINGS

Rating Pin Symbol Value Unit

Power Supply Voltage 4, 19 VCC (max) 6.5 Vdc
RF Input Voltage 22 RF

in

1.0 Vrms

Junction Temperature – T

J

+150 °C

Storage Temperature Range – T

stg

– 65 to +150 °C

RECOMMENDED OPERATING CONDITIONS

Rating Pin Symbol Value Unit

Power Supply Voltage 4, 19 V

CC

2.0 to 6.0 Vdc

Maximum 1st IF – f

IF1

21 MHz

Maximum 2nd IF – f

IF2

3.0 MHz

Ambient Temperature Range – T

A

– 40 to + 85 °C

ELECTRICAL CHARACTERISTICS (T

A

= 25°C, VCC = 4.0 Vdc, fo = 49.7 MHz, f

MOD

= 1.0 kHz, Deviation = ±3.0 kHz, f

1st LO

= 39 MHz, f

2nd

LO = 10.245 MHz, IF1 = 10.7 MHz, IF2 = 455 kHz, unless otherwise noted. All measurements performed in the test circuit of Figure 1.)

Characteristic

Condition Symbol Min Typ Max Unit

Total Drain Current No Input Signal I

CC

– 4.0 6.0 mAdc

Sensitivity (Input for 12 dB SINAD) Matched Input V

SIN

– 1.0 – µVrms

Recovered Audio VRF = 1.0 mV AF

O

mVrms
MC13135 170 220 300
MC13136 215 265 365

Limiter Output Level V

LIM

mVrms
(Pin 14, MC13136) – 130 –

1st Mixer Conversion Gain VRF = – 40 dBm MX

gain1

– 12 – dB

2nd Mixer Conversion Gain VRF = – 40 dBm MX

gain2

– 13 – dB

First LO Buffered Output – V

LO

– 100 – mVrms
Total Harmonic Distortion VRF = – 30 dBm THD – 1.2 3.0 %
Demodulator Bandwidth – BW – 50 – kHz
RSSI Dynamic Range – RSSI – 70 – dB
First Mixer 3rd Order Intercept TOI

Mix1

dBm

(Input) Matched – –17 –

Unmatched – –11 –

Second Mixer 3rd Order Matched TOI

Mix2

dBm

Intercept (RF Input) Input – –27 –

First LO Buffer Output Resistance – R

LO

– – – Ω
First Mixer Parallel Input Resistance – R – 722 – Ω
First Mixer Parallel Input Capacitance – C – 3.3 – pF
First Mixer Output Impedance – ZO – 330 – Ω
Second Mixer Input Impedance – Z

I

– 4.0 – kΩ
Second Mixer Output Impedance – ZO – 1.8 – kΩ
Detector Output Impedance – ZO – 25 – Ω

MC13135 MC13136

3

MOTOROLA ANALOG IC DEVICE DATA

TEST CIRCUIT INFORMA TION

Although the MC13136 can be operated with a ceramic
discriminator, the recovered audio measurements for both
the MC13135 and MC13136 are made with an LC quadrature
detector. The typical recovered audio will depend on the
external circuit; either the Q of the quad coil, or the RC
matching network for the ceramic discriminator. On the
MC13136, an external capacitor between Pins 13 and 14 can
be used with a quad coil for slightly higher recovered audio.
See Figures 10 through 13 for additional information.

Since adding a matching circuit to the RF input increases
the signal level to the mixer, the third order intercept (TOI)
point is better with an unmatched input (50 Ω from Pin 21 to
Pin 22). Typical values for both have been included in the
Electrical Characterization Table. TOI measurements were
taken at the pins with a high impedance probe/spectrum
analyzer system. The first mixer input impedance was
measured at the pin with a network analyzer.

Figure 1.

V

CC

39 k

455 kHz

Quad Coil

39 k

0.1

12

16

15
14
13

AF

Limiter

Demod

Figure 1b. MC13136 Quad Detector Test Circuit

24

0.2 µH

RF
Input

62 pF

0.001

23

22

21

20

19

18

180 p

0.01

0.1
360

Ceramic
Filter

10.7 MHz

455 kHz
Quad
Coil

39 k

39 k

0.1

8.2 k

17

16

15
14
13

12

0.1

0.01

3

2

1

4
5

6
7

8

9

10

11

0.1

0.1

0.1

Ceramic

Filter

455 kHz

10.245

MHz Xtal

39.0
MHz

Xtal

20 p

5.0 p

50 p

5.0 k

120 p

0.1

V

CC

0.1

1.0 k

0.84

µ

H

AF

VCC2

2nd LO

VCC1

1st LO

Varicap

Limiter

Demod

Figure 1a. MC13135 Test Circuit

MC13135 MC13136

4

MOTOROLA ANALOG IC DEVICE DATA

N

S+N, N, AND AMR (dB)

10

–130

RFin, RF INPUT (dBm)

f, FREQUENCY (MHz)

48.0

1.0
VB, VARACTOR BIAS VOLTAGE (Vdc)

RSSI OUTPUT (mVdc, Pin 12)

1400

–140

RF INPUT (dBm)

POWER (dBm)

30

–100

RFin, RF INPUT (dBm)

C

P

, EQUIVALENT PARALLEL CAPACITANCE (pF)

25

0.5
VB, VARACTOR BIAS VOLTAGE, V

Pin24

to V

Pin 23

(Vdc)

Figure 2. Supply Current versus Supply Voltage Figure 3. RSSI Output versus RF Input

Figure 4. Varactor Capacitance, Resistance

versus Bias Voltage

Figure 5. Oscillator Frequency

versus Varactor Bias

I

CC

, SUPPLY CURRENT (mA)

Figure 6. Signal Levels versus RF Input

6.0

0

VCC, SUPPLY VOLTAGE (V)

Figure 7. Signal + Noise, Noise, and

AM Rejection versus Input Power

RFin = 49.7 MHz
f

MOD

= 1.0 kHz

f

DEV

=

±

3.0 kHz

5.0

4.0

3.0

2.0

1.0

0

1.0 2.0 3.0 4.0 5.0 6.0 7.0 8.0

VCC = 4.0 V
RFin = 49.67 MHz
f

MOD

= 1.0 kHz

f

DEV

=

±

3.0 kHz

1200

1000

800

600

400

200

–120 –100 – 80 – 60 – 40 – 20

CP, f = 150 MHz

20

15

10

5.0

0

1.0 1.5 2.0 2.5 3.0 3.5 4.0

10

8.0

6.0

4.0

2.0

0

R

P

, EQUIVALENT PARALLEL RESISTANCE (k )

Ω

47.5

47.0

46.5

46.0

45.5

45.0

RP, f = 50 MHz

CP, f = 50 MHz

RP, f = 150 MHz

2.0 3.0 4.0 5.0 6.0

–90 –80 –70 –60 –50 –40 –30 –20

10

–10

–30

–50

–70

First Mixer Output

First Mixer Input

–110 – 90 – 70 – 50 – 30

0

–10
–20
–30
–40
–50
–60
–70

S + N

S + N 30% AM

VCC = 4.0 Vdc
RFin = 49.67 MHz
f

MOD

= 1.0 kHz

f

DEV

=

±

3.0 kHz

5.0 p

0.61

µ

H

1st LO

Varicap

500 p

500 p

1.0 M

Ω

0.2 µF

V

B

24
23

2

1

27 p

Second Mixer Output

Second Mixer Input

MC13135 MC13136

5

MOTOROLA ANALOG IC DEVICE DATA

RA, RECOVERED AUDIO (mV )

pp

RA, RECOVERED AUDIO (mV )

, EXCESS PHASE (DEGREES)

φ

f

DEV

, DEVIATION (kHz)

THD, TOT AL HARMONIC DISTORTION (%)

8.0

f

DEV

, DEVIATION (kHz)

MIXER OUTPUT (dB)

20

–100

RF INPUT (dBm)

1000

±

3.0

2000

±

1.0
f

DEV

, DEVIATION (kHz)

Figure 8. Op Amp Gain and Phase

versus Frequency

Figure 9. First Mixer Third Order Intermodulation

(Unmatched Input)

Figure 10. Recovered Audio versus

Deviation for MC13135

Figure 11. Distortion versus

Deviation for MC13135

A

V

, GAIN (dB)

Figure 12. Recovered Audio versus

Deviation for MC13136

50

10 k

f, FREQUENCY (Hz)

Figure 13. Distortion versus

Deviation for MC13136

30

10

–10

–50

100 k 1.0 M 10 M

3rd Order
Intermod
Products

0

–20

–40

–60

–80

–100

– 80 –60 –40 – 20 0

1500

1000

1.0

R = 68 k

Ω

800

600

400

200

0

–30

80

120

160

200

280

240

Phase

Gain

Desired Products

±

3.0

±

5.0

±

7.0

±

9.0

pp

R = 47 k

Ω

R = 39 k

Ω

±

1.0

±

3.0

±

5.0

±

7.0

±

9.0

7.0

6.0

5.0

4.0

THD, TOT AL HARMONIC DISTORTION (%)

R = 68 k

Ω

R = 47 k

Ω

±

4.0

±

5.0

±

6.0

±

7.0

±

8.0

±

9.0

R =

∞

C = 660 pF

10

8.0

6.0

4.0

2.0

0

f

DEV

, DEVIATION (kHz)

±

3.0

±

4.0

±

5.0

±

6.0

±

7.0

±

8.0

±

9.0

R = 2.7 k

Ω

C = 270 pF

R = 2.7 k

Ω

C = 270 pF

R = 1.2 k

Ω

C = 100 pF

R

13

V

CC

455 kHz

Quad Coil

T oko 7MC–8128Z

500

0

3.0

2.0
R = 39 k

Ω

R

13

V

CC

muRata
455 kHz
Resonator
CDB455C34

R

14
13

C

V

CC

muRata
455 kHz
Resonator
CDB455C34

R

14
13

C

V

CC

R = 1.2 k

Ω

C = 100 pF

455 kHz

Quad Coil

T oko 7MC–8128Z

R =

∞

C = 660 pF

0

MC13135 MC13136

6

MOTOROLA ANALOG IC DEVICE DATA

CIRCUIT DESCRIPTION

The MC13135/13136 are complete dual conversion
receivers. They include two local oscillators, two mixers, a
limiting IF amplifier and detector, and an op amp. Both
provide a voltage buffered RSSI with 70 dB of usable range,
isolated tuning diode and buffered LO output for PLL
operation, and a separate VCC pin for the first mixer and LO.
Improvements have been made in the temperature
performance of both the recovered audio and the RSSI.

V

CC

Two separate VCC lines enable the first LO and mixer to
continue running while the rest of the circuit is powered down.
They also isolate the RF from the rest of the internal circuit.

Local Oscillators

The local oscillators are grounded collector Colpitts, which
can be easily crystal–controlled or VCO controlled with the
on–board varactor and external PLL. The first LO transistor is
internally biased, but the emitter is pinned–out and IQ can be
increased for high frequency or VCO operation. The collector
is not pinned out, so for crystal operation, the LO is generally
limited to 3rd overtone crystal frequencies; typically around
60 MHz. For higher frequency operation, the LO can be
provided externally as shown in Figure 16.

Buffer

An amplifier on the 1st LO output converts the
single–ended LO output to a differential signal to drive the
mixer. Capacitive coupling between the LO and the amplifier
minimizes the effects of the change in oscillator current on
the mixer. Buffered LO output is pinned–out at Pin 3 for use
with a PLL, with a typical output voltage of 320 mVpp at V

CC

= 4.0 V and with a 5.1 k resistor from Pin 3 to ground. As seen
in Figure 14, the buffered LO output varies with the supply
voltage and a smaller external resistor may be needed for low
voltage operation. The LO buffer operates up to 60 MHz,
typically. Above 60 MHz, the output at Pin 3 rolls off at
approximately 6.0 dB per octave. Since most PLLs require
about 200 mVpp drive, an external amplifier may be required.

Figure 14. Buffered LO Output Voltage

versus Supply Voltage

600

500

400

300

200

100

VCC, SUPPLY VOLTAGE (Vdc)

2.5

3.0 3.5 4.0 4.5 5.0 5.5

R

Pin3

= 3.0 k

Ω

R

Pin3

= 5.1 k

Ω

OUTPUT (mV )

pp

Mixers

The first and second mixer are of similar design. Both are
double balanced to suppress the LO and input frequencies to
give only the sum and difference frequencies out. This
configuration typically provides 40 to 60 dB of LO
suppression. New design techniques provide improved mixer
linearity and third order intercept without increased noise.
The gain on the output of the 1st mixer starts to roll off at
about 20 MHz, so this receiver could be used with a 21 MHz
first IF. It is designed for use with a ceramic filter, with an
output impedance of 330 Ω. A series resistor can be used to
raise the impedance for use with a crystal filter, which
typically has an input impedance of 4.0 kΩ. The second mixer
input impedance is approximately 4.0 kΩ; it requires an
external 360 Ω parallel resistor for use with a standard
ceramic filter.

Limiting IF Amplifier and Detector

The limiter has approximately 110 dB of gain, which starts
rolling off at 2.0 MHz. Although not designed for wideband
operation, the bandwidth of the audio frequency amplifier has
been widened to 50 kHz, which gives less phase shift and
enables the receiver to run at higher data rates. However,
care should be taken not to exceed the bandwidth allowed by
local regulations.

The MC13135 is designed for use with an LC quadrature
detector, and does not have suf ficient drive to be used with a
ceramic discriminator. The MC13136 was designed to use a
ceramic discriminator, but can also be run with an LC quad
coil, as mentioned in the T est Circuit Information section. The
data shown in Figures 12 and 13 was taken using a muRata
CDB455C34 ceramic discriminator which has been specially
matched to the MC13136. Both the choice of discriminators
and the external matching circuit will affect the distortion and
recovered audio.

RSSI/Op Amp

The Received Signal Strength Indicator (RSSI) on the
MC13135/13136 has about 70 dB of range. The resistor
needed to translate the RSSI current to a voltage output has
been included on the internal circuit, which gives it a tighter
tolerance. A temperature compensated reference current
also improves the RSSI accuracy over temperature. On the
MC13136, the op amp on board is connected to the output to
provide a voltage buffered RSSI. On the MC13135, the op
amp is not connected internally and can be used for the RSSI
or as a data slicer (see Figure 17c).

MC13135 MC13136

7

MOTOROLA ANALOG IC DEVICE DATA

Figure 15. PLL Controlled Narrowband FM Receiver at 46/49 MHz

Figure 16. 144 MHz Single Channel Application Circuit

24

0.2

µ

H

RF
Input

62 pF

0.001

23

22

21

20

19

18

150 pF

0.01

0.1
360

Ceramic

Filter

10.7 MHz

455 kHz

Quad Coil

68 k

0.15

1.0 k

17

16

15
14
13

12

0.1

500 p

3

2

1

4

5
6
7

8

9

10

11

0.1

0.1

Ceramic

Filter

455 kHz

10.245

MHz Xtal

27 p

5.0 p

50 p

5.1 k

120 p

0.1

V

CC

47 k

0.68

µ

H

AF

VCC2

2nd LO

VCC1

1st LO

Varicap

Limiter

Demod

Recovered

Audio

RSSI

Output

10 k

500 p

100 k

1.0

0.01

Fin1

0.1

0.1

2.7 k

MC145166

3.0 p

MPS5179

0.05

µ

H

0.07

µ

H

39 p

1.0

µ

5.1 k
L3

12 p

3300 p

To Mixer

15 k

3300 p

470 p

470

L2

RF Input

12 p

Q1

Preamp for MC13135 at 144.455 MHz

1st LO

External Oscillator Circuit

L1

X1

43 p

68 p

5.6 k

1.0 k

100 p

15 k

0.82

µ

1.0 µF

15 p

V

CC

1000p

Q1

470

MPS5179

44.585 MHz 3rd Overtone
Series Resonant Crystal

0.078

µ

H Inductor

(Coilcraft Part # 146–02J08)

f

osc

=

133.755 MHz

1.0 µF

V

CC

OSC
Out

OSC

In

PD1
PD2

LD

D3

Fin2

VDD
D0
D1

D2

MC13135

Q1 –

L2 –
L3 –

Q1 –
X1 –

L1 –

VSS

+

+

MC13135 MC13136

8

MOTOROLA ANALOG IC DEVICE DATA

Figure 17a. Single Channel Narrowband FM Receiver at 49.7 MHz

Figure 17b. PC Board Component View

Figure 17c. Optional Data Slicer Circuit

(Using Internal Op Amp)

24

0.2

µ

H

RF Input
50

Ω

Source

62 pF

0.001

23

22
21

20

19

18

150 p

0.01

0.1
360

Ceramic
Filter

10.7 MHz

455 kHz

Quad Coil

10 k

39 k

0.15

1.0 k

17

16

15
14

13

12

0.1

2200 p

3

2

1

4
5

6
7

8

9

10
11

0.1

0.1

Ceramic

Filter

455 kHz

10.245 MHz
Xtal

39 MHz
Xtal

27 p

5.0 p

50 p

5.1 k

120 p

0.1

V

CC

1.0

1.0 k

1.0

µ

H

AF

VCC2

2nd LO

VCC1

1st LO

Varicap

Limiter

Demod

Buffered LO

Output

Recovered
Audio

RSSI
Output

0.01

MC13135

0.001

V

CC

1.0 M

V

in

(Pin 17)

20 k

20 k

16

15
14

10 k

FSK Data
Output

10 k

NOTES:1. 0.2 µH tunable (unshielded) inductor

2. 39 MHz Series mode resonant
3rd Overtone Crystal

3. 1.5 µH tunable (shielded) inductor

4. 10.245 MHz Fundamental mode crystal,
32 pF load

5. 455 kHz ceramic filter, muRata CFU 455B
or equivalent

6. Quadrature coil, Toko 7MC–8128Z (7mm)
or Toko RMC–2A6597HM (10mm)

7. 10.7 MHz ceramic filter, muRata SFE10.7MJ–A
or equivalent

Figure 17.

5.1k

50p

51K

10k

10.7 MHz

0.1

150p

2200p

27p
5p

0.1

120p

0.1

0.1

0.1
39K

0.1

0.22

0.15

1.0k

360

0.01

62p

.001

1.0 k

39 MHz

10.245 MHz

1.0

10

+4.7

+10

MC34119

MC13135

XT

XT

CF

+

CF

455 KHz

6

3

4

5

2

1

7

+

+

0.01

10k

MC13135 MC13136

9

MOTOROLA ANALOG IC DEVICE DATA

AUDIO

V

GROUND

RSSI

CC

V

CC2

SPEAKER

L.O.

RF IN

MC13135
MC13136

Figure 18. PC Board Solder Side View

Figure 19. PC Board Component View

(Circuit Side View)

NOTES:1. 0.2 µH tunable (unshielded) inductor

2. 39 MHz Series mode resonant
3rd Overtone Crystal

3. 1.5 µH tunable (shielded) inductor

4. 10.245 MHz Fundamental mode crystal,
32 pF load

5. 455 kHz ceramic filter, muRata CFU 455B
or equivalent

6. Ceramic discriminator, muRata CDB455C34
or equivalent

7. 10.7 MHz ceramic filter, muRata SFE10.7MJ–A
or equivalent

3.375

″

3.25

″

5.1k

50p

51K

10k

10.7 MHz

0.1

150p

2200p

27p
5p

0.1

120p

0.1

0.1

0.1

2.7k

0.1

0.22

0.15

1.0k

360

0.01

62p

.001

1.0 k

39 MHz

10.245 MHz

1.0

10

+4.7

+10

MC34119

MC13136

XT

XT

CF

+

CF

455 KHz

3

4

5

2

1

7

+

270p

6

0.01

10k

MC13135 MC13136

10

MOTOROLA ANALOG IC DEVICE DATA

V

CC

Figure 20a. Single Channel Narrowband FM Receiver at 49.7 MHz

Figure 20b. Optional Audio Amplifier Circuit

0.22

10 k

51 k

10

4.7

10

Speaker

MC341 19

1
2

3
4

8
7

6
5

Recovered

Audio

24

0.2

µ

H

RF Input
50

Ω

Source

62 pF

0.001

23

22

21

20

19

18

150 pF

0.01

0.1
360

Ceramic
Filter

10.7 MHz

muRata

455 kHz

Resonator

CDB455C34

10 k

2.7 k

0.15

1.0 k

17

16

15
14

13

12

0.1

2200 p

3

2

1

4
5

6

7

8

9

10

11

0.1

0.1

Ceramic

Filter

455 kHz

10.245 MHz
Xtal

39 MHz
Xtal

27 p

5.0 p

50 p

5.0 k

120 p

0.1

V

CC

1.0

1.0 k

1.0

µ

H

AF

VCC2

2nd LO

VCC1

1st LO

Varicap

Limiter

Demod

Buffered LO

Output

Recovered
Audio

RSSI
Output

0.01

270 p

MC13136

Figure 20.

+

+

+

+

MC13135 MC13136

11

MOTOROLA ANALOG IC DEVICE DATA

Figure 21. MC13135 Internal Schematic

V

CC

1 V

CC

2

V

EE

V

CC

2

V

EE

V

CC

2

V

EE

V

EE

V

CC

2

V

EE

V

CC

2

V

EE

1.0 k

21

5.0 p

12

16

17

7

4.0 k

4.0 k6.0 k

6

5

20

14

15

Bias

8.0 k15 k

1

2

1.0 k

22

3

9

10

11

2.0 k

52 k

50 k

100

First LO First Mixer

Second LO Second Mixer

Limiting IF Amplifier

Detector and Audio Amplifier

13

1.6 k

100 k

Op Amp

12 k

Figure 21.

This device contains 142 active transistors.

5.0 p

18

MC13135 MC13136

12

MOTOROLA ANALOG IC DEVICE DATA

Figure 22. MC13136 Internal Schematic

V

CC

2

V

EE

V

CC

2

V

EE

V

CC

2

V

EE

V

CC

2

V

EE

5.0 p

12

16

17

14

15

Bias

9

10

11

2.0 k

52 k

50 k

Limiting IF Amplifier

Detector and Audio Amplifier

13

100 k

Op Amp

Figure 22.

This device contains 142 active transistors.

V

CC

1 V

CC

2

V

EEV

EE

1.0 k

21

7

4.0 k

4.0 k6.0 k

6

5

20

8.0 k15 k

1

2

1.0 k

22

3

100

First LO First Mixer

Second LO Second Mixer

1.6 k

12 k

5.0 p

18

MC13135 MC13136

13

MOTOROLA ANALOG IC DEVICE DATA

OUTLINE DIMENSIONS

P SUFFIX

PLASTIC PACKAGE

CASE 724–03

ISSUE D

DW SUFFIX

PLASTIC PACKAGE

CASE 751E–04

(SO–24L)

ISSUE E

MIN MINMAX MAX

INCHES MILLIMETERS

DIM

1.265

0.270

0.175

0.020

0.060

0.012

0.140
15

°

0.040

0.050 BSC

0.100 BSC

0.300 BSC

1.27 BSC

2.54 BSC

7.62 BSC

A
B
C
D
E

F

G

J

K

L
M
N

31.25

6.35

3.69

0.38

1.02

0.18

2.80
0

°

0.51

32.13

6.85

4.44

0.51

1.52

0.30

3.55
15

°

1.01

1.230

0.250

0.145

0.015

0.040

0.007

0.110
0

°

0.020

NOTES:

1. CHAMFERED CONTOUR OPTIONAL.

2. DIMENSION L TO CENTER OF LEADS WHEN
FORMED PARALLEL.

3. DIMENSIONING AND TOLERANCING PER ANSI
Y14.5M, 1982.

4. CONTROLLING DIMENSION: INCH.

112

1324

–A–

–B–

C

K

N

–T–

SEATING
PLANE

G

E

F

D

24 PL

J 24 PL

M

NOTE 1

L

0.25 (0.010) T A

M M

0.25 (0.010) T B

M M

T

0.010 (0.25) A B

M

S S

MIN MINMAX MAX

MILLIMETERS INCHES

DIM

A
B
C
D
F
G

J
K
M
P
R

15.25

7.40

2.35

0.35

0.41

0.23

0.13
0

°

10.05

0.25

15.54

7.60

2.65

0.49

0.90

0.32

0.29
8

°

10.55

0.75

0.601

0.292

0.093

0.014

0.016

0.009

0.005
0

°

0.395

0.010

0.612

0.299

0.104

0.019

0.035

0.013

0.011
8

°

0.415

0.029

1.27 BSC 0.050 BSC

NOTES:

1. DIMENSIONING AND TOLERANCING PER ANSI
Y14.5M, 1982.

2. CONTROLLING DIMENSION: MILLIMETER.

3. DIMENSIONS A AND B DO NOT INCLUDE
MOLD PROTRUSION.

4. MAXIMUM MOLD PROTRUSION 0.15 (0.006)
PER SIDE.

5. DIMENSION D DOES NOT INCLUDE DAMBAR
PROTRUSION. ALLOWABLE DAMBAR
PROTRUSION SHALL BE 0.13 (0.005) TOTAL IN
EXCESS OF D DIMENSION AT MAXIMUM
MATERIAL CONDITION.

–A–

–B–

112

24 13

–T–

C

K

SEATING
PLANE

R X 45°

G 22 PL

P 12 PL

0.010 (0.25)

B

M M

F

J

M

D 24 PL

MC13135 MC13136

14

MOTOROLA ANALOG IC DEVICE DATA

NOTES

MC13135 MC13136

15

MOTOROLA ANALOG IC DEVICE DATA

NOTES

MC13135 MC13136

16

MOTOROLA ANALOG IC DEVICE DATA

Motorola reserves the right to make changes without further notice to any products herein. Motorola makes no warranty , representation or guarantee regarding
the suitability of its products for any particular purpose, nor does Motorola assume any liability arising out of the application or use of any product or circuit, and
specifically disclaims any and all liability, including without limitation consequential or incidental damages. “T ypical” parameters which may be provided in Motorola
data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals”
must be validated for each customer application by customer’s technical experts. Motorola does not convey any license under its patent rights nor the rights of
others. Motorola products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other
applications intended to support or sustain life, or for any other application in which the failure of the Motorola product could create a situation where personal injury
or death may occur. Should Buyer purchase or use Motorola products for any such unintended or unauthorized application, Buyer shall indemnify and hold Motorola
and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees
arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that
Motorola was negligent regarding the design or manufacture of the part. Motorola and are registered trademarks of Motorola, Inc. Motorola, Inc. is an Equal
Opportunity/Affirmative Action Employer.

How to reach us:
USA/EUROPE /Locations Not Listed: Motorola Literature Distribution; JAPAN: Nippon Motorola Ltd.; Ta tsumi–SPD–JLDC, 6F Seibu–Butsuryu–Center,

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INTERNET: http://Design–NET.com 51 Ting Ko k Road, Tai Po, N.T., Hong Kong. 852–26629298

MC13135/D

*MC13135/D*

◊