SANYO LA3410

Ordering number:ENN1407F
Monolithic Linear IC
LA3410
VCO Non-Adjusting PLL FM MPX
Stereo Demodulator with FM Accessories
Overview
Package Dimensions
The LA3410 is a multiplex demodulator IC designed for
FM stereo tuner. It features the VCO non-adjusting function that eliminates the need to adjust the free-running frequency of VCO.
unit:mm
3006B-DIP16
16
9
1
8
7.62
Applications
0.25
• Home stereos, portable hi-fi sets.
6.4
[LA3410]
Functions
19.2
3.4
3.0
3.65max
• VCO non-adjusting function.
• PLL MPX stereo demodulator.
• Gain variable type post amplifier.
• VCO stop function.
• Separation adjust function.
0.71
2.54
0.48
1.2
SANYO : DIP16
Features
• Non-adjusting VCO : Eliminates the need to adjust the
free-running frequency.
• Good temperature characteristic of VCO : ±0.1% typ. for
±50°C change.
• Low distortion at high frequencies in stereo main channel
(0.06% at f=10kHz) (Non-adjusting PLL makes the capture range narrower, leading to improvement in beat distortion at high frequencies in stereo main channel.)
• Low distortion : 1kHz 300mV input mono 0.025% typ.
main 0.02% typ.
• High S/N : 91dB typ. (mono 300mV input, LPF).
92dB typ. (mono 300mV input, IHF BPF).
• High voltage gain : Approximately 8.5dB (at standard
constants).
• Wide dynamic range : Distortion 1.0% at mono 800mV,
1kHz input.
• Good ripple rejection of power supply : 34dB typ.
Any and all SANYO products described or contained herein do not have specifications that can handle
applications that require extremely high levels of reliability, such as life-support systems, aircraft’s
control systems, or other applications whose failure can be reasonably expected to result in serious
physical and/or material damage. Consult with your SANYO representative nearest you before using
any SANYO products described or contained herein in such applications.
SANYO assumes no responsibility for equipment failures that result from using products at values that
exceed, even momentarily, rated values (such as maximum ratings, operating condition ranges,or other
parameters) listed in products specifications of any and all SANYO products described or contained
herein.
SANYO Electric Co.,Ltd. Semiconductor Company
TOKYO OFFICE Tokyo Bldg., 1-10, 1 Chome, Ueno, Taito-ku, TOKYO, 110-8534 JAPAN
21000TH (KT)/90196RM/33194HO/O096KI/8024KI, TS No.1407–1/13
LA3410
Specifications
Absolute Maximum Ratings at Ta = 25˚C
Parameter
Maximum Supply Voltage
Symbol
Conditions
Ratings
Unit
VCC max
16
V
Lamp Driving Current
IL max
30
mA
Allowable Power Dissipation
Pd max
480
mW
Ta≤60˚C
Operating Temperature
Topr
–20 to +75
˚C
Storage Temperature
Tstg
–40 to +125
˚C
Operating Conditions at Ta = 25˚C
Parameter
Recommended Supply Voltage
Operating Voltage Range
Recommended Input Signal Voltage
Symbol
Conditions
Ratings
VCC
VCC op
Unit
12
6.5 to 14
Vi
300
V
V
mV
Operating Characteristics at Ta = 25˚C, VCC=12V, Vi=300mV, f=1kHz, L+R=90%, pilot=10%
Parameter
Quiescent Current
Input Resistance
Conditions
Symbol
Icco
Ratings
min
typ
Quiescent
18.5
ri
Ripple Rejection of Power Supply
f=100Hz
Channel Separation
Sep
f=1kHz
40
f=10kHz
mono
Total Harmonic Distortion
THD
Allowable Input Level
Vi max
Signal-to-Noise Ratio
S/N
Lamp Lighting Level
VL
Lamp Hysteresis
Hy
kΩ
dB
45
dB
55
dB
42
dB
0.025
main f=1kHz
0.02
main f=10kHz
0.06
sub
0.02
0.15
%
0.15
%
0.15
mono (Note 1)
Channel Balance
CB
mono
80
91
dB
92
4
500
Carrier Leak
VCO Stop Voltage
%
mV
8
dB
17
3
dB
%
730
%
1000
mV
1
dB
31
5.5
mV
+0.8
–1.2
Vo
%
800
Capture Range
Output Voltage
%
700
mono, Rg=5.1kΩ, IHF BPF
Pilot level
mA
34
0.02
mono, Rg=5.1kΩ, LPF
28
20
main f=100Hz
THD=1%, mono
Unit
max
dB
VCC–3
V
Note 1 : The output voltage on pin 4 or 7 is measured after separation adjust.
No.1407–2/13
LA3410
Equivalent Circuit Block Diagram and Sample Application Circuit
* : Use a nonpolarized electrolytic capacitor or polyester film capacitor in the VCO stop mode. If a
polarized electrolytic capacitor is used, refer to
“VCO Stop Method” shown below.
X : Murata CSB456F11
Kyocera KBR-457HS
LPF L BL-13 (Korin Giken)
Note 1 :
Set the PLL loop filter constants (R8, C9, C10),
with the input pilot level considered, so that the
capture range becomes wide. (Refer to No. 4 or
Proper Cares in Using IC.)
Sample Printed Circuit Pattern
No.1407–3/13
LA3410
External Parts
Symbol
Capacitor
Kind
C1
Electrolytic capacitor
C2
Element Value
Remarks
100µF
Power supply ripple filter
Electrolytic capacitor
10µF
DC cut
C3 to 4
Ceramic capacitor
750pF
De-emphasis constant
C5 to 6
Electrolytic capacitor
10µF
DC cut
C7
Electrolytic capacitor
1µF
Sync detect filter
C8
Electrolytic capacitor
10µF
DC cut
C9
Non-polarized capacitor
0.47µF
Loop filter Note 1
C10
Non-polarized capacitor
3.3µF
Loop filter Note 1
C11
Polyester film capacitor
0.047µF
R1C3=R2C4=50µs, 75µs
DC cut
R1 to 2
Carbon film resistor
62kΩ
R3 to 6
Carbon film resistor
3.3kΩ
R7
Carbon film resistor
1kΩ
Lamp current limiting
R8
Carbon film resistor
1kΩ
Loop filter
Semifixed
Resistor
VR1
Carbon film resistor
350kΩ
Resonator
X
Ceramic resonator
CSB456F11
Murata
KBR457HS
Kyocera
Resistor
De-emphasis constant, post
amplifier feedback resistor
LPF input/output resistor
Separation adjust
Note 1 : IF C9, C10 are polarized capacitors, refer to “VCO Stop Method ™” shown below
Note 2 : For loop filter constants (C9, C10, R8), refer to 4. Capture range and PLL loop filter constants on page 5 and set
these constants to the optimum values for the input pilot level.
Voltage on Each Pin and Pin Name
Pin No.
Voltage [V]
1
VCC
Power supply
Pin Name
Remarks
2
3
4
5
6
7
8
3.0V
3.0V
3.0V
3.0V
3.0V
3.0V
0
MPX input
Composite amplifier output
Post amplifier output
Post amplifier input
Post amplifier input
Post amplifier output
GND
Input resistance 20kΩ
Output resistance 1kΩ
L output
Minus input
Minus input
R output
9
10
11
12
13
14
15
16
–
2.7V
2.7V
3.0V
2.7V
2.7V
2.7V
–
Stereo indicator
Pilot sync detect filter
Pilot sync detect filter VCP stop
Separation adjust
PLL input
PLL loop filter
PLL loop filter
OSC
IL max=30mA
Proper Cares in Using IC
1. VCO stop method
One of the following is used to stop VCO. The monaural mode is forced to be entered at the time of VCO stop.
(1) VCO stop method ¡
(a) For loop filter capacitors (C9, C10 in Fig. 1), use one of the following.
(1) Non-polarized capacitor
(2) Polyester film capacitor
[Reason] When in the VCO stop mode, external voltage VS causes an
unpolarized voltage of approximately 1.5V to be developed
across pins 14 and 15.
(b) Setting of external voltage VS and limiting resistor RS.
The relation between VS and RS is shown in Fig. 9. When in the VCO stop mode, the value of RS must be set so
that the voltage on pin 11 is within the specified range (min=5.5V, max=VCC–3V). For example, it is seen from
Fig. 9 that the value of limiting resistor RS is approximately 4.2kΩ when the voltage on pin 11 is set to 6V at
VS=12V.
No.1407–4/13
LA3410
(2) VCO stop method ™
(a) Addition of diode (small-signal silicon diode)
Diode D1 is additionally connected across pins 11 and 15 as shown in
Fig. 2. In this case, the use of nonpolarized capacitors for C9, C10 across
pins 14 and 15 involves no problem (pin 15 : + polarity).
(Note) When D1 is connected across pins 11 and 14, stereo start time may
be 2 to 3 seconds late as compared with the application in Fig. 2.
(b) Setting of external voltage VS and limiting resistor RS.
The relation between VS and RS is shown in Fig. 10. When in the VCO stop mode, the value of RS must be set so
that the voltage on pin 11 is within the specified range (min=5.5V, max=VCC–3V). For example, it is seen from
Fig.10 that the value of limiting resistor RS is approximately 2.2kΩ when the voltage on pin 11 is set to 6V at
VS=12V.
2. Checking of free-running frequency
Since no pin is provided for checking the free-running frequency, the free-running
frequency is checked through a burrer amplifier with a high input impedance, low
input capacitance connected to pin 16. Fig. 3 shows a sample circuit configuration.
The frequency measured in this circuit configuration is 456kHz or thereabouts. The
frequency in 19kHz equivalent can be obtained by dividing this measured value by 24.
The wiring across pin 16 and the buffer amplifier input must be made as short as
possible (within 1cm).
3. Ceramic resonator
Ceramic resonators other than specified cannot be used in applications of the LA3410. The Type No., manufacturer of
the ceramic resonators specified are shown below. For particulars about the ceramic resonator, contact the mamufacturer.
Type No.
Manufacturer
CSB456F11
Murata
KBR-457HS
Kyocera
4. Capture range and PLL loop filter constants
(1) Definition of capture range
Since the VCO of the LA3410 is adjustment-free, the capture range is defined by the following formula with the
deviation of the free-running frequency from the pilot signal considered.
Capture range C. R=
F0–F1 – F0–456
F1
456
× 100 [%]
F0 : Free-running frequncy
F1 : Lock frequency when the input frequency is varied
No.1407–5/13
LA3410
(2) PLL loop filter constants
(a) The capture range of the LA3410 depends primarily on input pilot level and PLL loop filter
constants C9 and R8 as shown in Fig. 4-A.
It is necessary to set C9 and R8, with the input pilot level considered, so that the capture
range becomes wide but the stereo distortion
is kept rather low. The transfer function of the
loop filter is given by :
Lag filter F (S)=
1
SC9R0+1
Lag Lead filter F (S)=
SC10R8+1
SC10 (R0+R8)+1
R0 : IC internal resistance
and the response is given by Fig.4-B. The capture range may be made wide by the following methods.
¡ Set 3 high to make the band width wide (Decrease C9).
™ Increase the high frequency gain F (∞) so long
as the characteristic of the Lag Lead filter is
not lost (Increases R8).
Fig. 4-C shows the capture range characteristic when C9 and R8 are varied. When R8 is
increased, the capture range will increase to a
certain point. R8 must be set in this range.
When R8 is increased, the STEREO-L, R distortion may worsen at low frequencies (100
to 400Hz). In this case, connect a capacitor of
200 to 1000pF across pin 3 and GND to improve the STEREO-L, R distortion (Refer to
Fig. 5).
(3) Fig. 4-D shows the capature range characteristic when C10 is varied. The adequate value of
C10, which depends on C9 and R8, is 0.33 to
3.3µF. If the value of C10 is decreased too
much, the capture range will decrease as seen
from Fig. 3 ; and if increased too much, the
stereo start time after VCO STOP release will
be made late.
No.1407–6/13
LA3410
(4) When C9 is decreased, the capture range will
widen but the stereo main distortion at f=10kHz
will worsen (beat distortion). This data is shown
in Fig. 4-E. Set C2 so that the stereo distortion
is kept rather low.
(5) The data on pilot level vs. capture range is
shown in Fig. 4-F to G. It is necessary to set the
loop filter constants, with the input pilot level
considered, so that the capture range becomes
wide. For example, when the LA1260 is used
for IF IC, the minimum demodulation output
will be 183mV (100% mod) and the stereo operation must be performed at pilot level 12mV
with a pilot margin allowed. In this case,
C2=0.1µF, R1=6.8 to 10kΩ are recommended.
5. Improvement in sub, stereo (R) distortions worsened at low frequencies.
There are some cases where the sub, stereo (R) distortions are worsened
at low frequencies. One cause for this worsening is the phase shift between 38kHz and 19kHz in the flip-flop inside the IC. This shift is improved by connecting a phase compensating capacitor across pin 3 and
GND as shown in Fig. 5. The CD value differs with each IF (the phase
shift between the sub signal and pilot signal in the composite signal
differs with each IF). An adequate value is 200 to 1500pF.
No.1407–7/13
LA3410
6. Separation adjust
The separatin is adjusted by varying the main signal level in the composite signal. The main signal is applied to the post
amplifier input through amplifiers A1, A3. The input level in A3 is varied by internal resistor RA and external variable
resistor VR1. Therefore, the output main signal becomes 0 at VR1=0 and is maximized at VR1=∞. The separation is
presettable if VR1 is set to an adequate value. In this case, the VR1 value differs with each set ; X of VR1 is approxmately
150kΩ when the ratio of the main signal and sub signal at the LA3410 input is 1 : 1 and the sub signal and pilot signal
are in phase. The separation, when preset, varies 30dB min. with the variations in the IC only considered. If the value
of capacitor C8 for DC cut is decreased, the separation gets worse at low frequencies.
7. Post amplifier oscillation when loaded capacitively (inductively)
If the post amplifier outputs (pins 4, 7) are loaded capacitively (inductively), oscillation may occur. When connecting
a low-pass filter to each of the outputs, an input resistor must be connected across the post amplifier output and the lowpass filter and the wiring across these points must be made as short as possible.
8. Forced monaural mode
The following method is used to provide the forced monaural mode. In this case, VCO oscillation does not stop. The
above-mentioned VCO stop method is used to stop VCO oscillation.
· Connect pin 10 to GND through a resistor of 10kΩ.
Other application circuit
1. How to improve the dynamic range of the post amplifier
The amplifier bias voltage is set low (3.0V) so that the LA3410 is capable of being operated from low voltage. If the
supply voltage is high, the following method can be used to extend the dynamic range.
Fig. 6 shows how to extend the dynamic range of the post amplifier. When RB is not used, the DC voltage across pins
4 and 7 is 3.0V. The DC volatage across pins 4 and 7 can be increased to extend the dynamic range of the post amplifier.
Pins 5, 6, being minus input pins of the post amplifier, are virtual GND
points. By connecting RB across pin 5 and GND and across pin 6 and GND,
the DC voltages on pins 4, 7 are obtained as follows :
3.0
RB+R1
R
=3.0 (1+ 1 )
RB
RB
3.0
RB+R2
R
=3.0 (1+ 2 )
RB
RB
The upper and lower loss voltages of the post amplifier are approximately
2V and 0.5V respectively. With these loss voltages considered, the voltages
on pins 4, 7 are set. For example, Figs. 11, 12 show how the dynamic range
is improved when the DC voltages on pins 4, 7 are set to approximately
5.2V with upper loss voltage 2V and lower loss voltage 0.5V of the post
amplifier considered. Fig. 11 shows the characteristic where no RB is connected ; Fig. 12 shows the characteristic where RB=82kΩ is connected.
2. Feedback resistance of post amplifier and total gain
Table 2 shows the feedback resistance of the post amplifier and the total gain. Fig. 13 shows the distortion vs. feedback
resistance characteristic. Figs. 14, 15 show the sample application circuits where R1 (R2) is 100kΩ and 130kΩ respectively.
R1 (R2)kΩ
C3 (C4)pF
Total gain [dB]
Output signal voltage typ [mV]
62
750
8.5
730
82
620
11
965
100
510
13
1177
130
390
15
1530
150
330
16
1766
180
270
17..5
2119
Table 2. R1 (R2), C3 (C4) – gain
No.1407–8/13
LA3410
Decoder circuit (Refer to the Block Diagram in the Sample Application Circuit.)
The LA3410 adopts a decoder circuit of chopper type. The sub signal sync-detected by this decoder is applied to the
post amplifier minus input through RB as shown in the Sample Application Circuit. This signal is matrixed with the
main signal coming out of A3. The demodulation method is, in a sense, a combination of switching method and matrix
method. The gain for the sub signal is :
VS
R1
2
·
RB
π
or VS
R2
2
·
RB
π
R1, R2 : Post amplifier feedback resistor
VS :
Peak value of input sub signal
The gain for the main signal is :
VM
VR1
R1
·
RA+VR1 RC
or VM
VR1
R2
·
RA+VR1 RC
VR1 :
VM :
Semifixed resistor for separation adjust
Peak value of input main signal
In the LA3410, the gain of the main signal is varied with VR1 to adjust the separation. The IF output is generally such
that the sub signal level is lower than the main signal level. In this case also, the separation can be adjusted.
3. De-emphasis
The de-emphasis characteristic depends on the feedback resistors, capacitors of the post amplifier. R1, R2, C3, C4 in
the Sample Application Circuit are set as R1C3=R2C4=50µs, 75µs. Table 3 shows the values of R1, R2, C3, C4 and the
de-emphasis constants.
Table 3
R1 (R2)
C2 (C4)50µs
C2 (C4)75µs
33kΩ
1500pF
2200pF
39kΩ
1200pF
2000pF
51kΩ
1000pF
1500pF
62kΩ
750pF
1000pF
82kΩ
620pF
910pF
110kΩ
470pF
680pF
130kΩ
390pF
560pF
The post amplifier requires feedback capacitors C3, C4 regardless of the de-emphasis characteristic. Without these
capacitors, the stereo distortion gets worse.
4. Low-pass filter
Fig. 8 shows a sample circuit configuration where an LC filter is used as the low-pass filter and Fig. 16 shows a sample
characteristic of this filter. As compared with the LPF (BL-13) in the Sample Application Circuit, the use of this filter
makes the attenuation less at 19kHz, 38kHz ; therefore, carrier leak at the LPF output causes the stereo distortion and
separation characteristic to get worse than specified in the Operating Characteristics. For the stereo distortion, the BL13 provides approximately 0.02%, while the LC filter provides approximately 0.5%
No.1407–9/13
LA3410
No.1407–10/13
LA3410
No.1407–11/13
LA3410
No.1407–12/13
LA3410
Specifications of any and all SANYO products described or contained herein stipulate the performance,
characteristics, and functions of the described products in the independent state, and are not guarantees
of the performance, characteristics, and functions of the described products as mounted in the customer's
products or equipment. To verify symptoms and states that cannot be evaluated in an independent device,
the customer should always evaluate and test devices mounted in the customer's products or equipment.
SANYO Electric Co., Ltd. strives to supply high-quality high-reliability products. However, any and all
semiconductor products fail with some probability. It is possible that these probabilistic failures could
give rise to accidents or events that could endanger human lives, that could give rise to smoke or fire,
or that could cause damage to other property. When designing equipment, adopt safety measures so
that these kinds of accidents or events cannot occur. Such measures include but are not limited to protective
circuits and error prevention circuits for safe design, redundant design, and structural design.
In the event that any or all SANYO products(including technical data,services) described or
contained herein are controlled under any of applicable local export control laws and regulations,
such products must not be expor ted without obtaining the expor t license from the authorities
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No part of this publication may be reproduced or transmitted in any form or by any means, electronic or
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or otherwise, without the prior written permission of SANYO Electric Co., Ltd.
Any and all information described or contained herein are subject to change without notice due to
product/technology improvement, etc. When designing equipment, refer to the "Delivery Specification"
for the SANYO product that you intend to use.
Information (including circuit diagrams and circuit parameters) herein is for example only ; it is not
guaranteed for volume production. SANYO believes information herein is accurate and reliable, but
no guarantees are made or implied regarding its use or any infringements of intellectual property rights
or other rights of third parties.
This catalog provides information as of February, 2000. Specifications and information herein are subject
to change without notice.
PS No.1407–13/13