NTE NTE1860

NTE1860
Integrated Circuit
TV Stereo Multiplexing Decoder
Description:
The NTE1860 is a bipolar IC for use in TV stereo multiplexing decoding, filters for stereo, and SAP
(Separate Audio Program) demodulation applications.
Features:
D Low number of external parts
D Excellent channel separation characteristics for stereo applications. Min. 46dB at 1kHz.
D Selection of individual modes of MAIN/SAP/BOTH.
D Direct driving mode for LED display.
Absolute Maximum Ratings: (TA = 25°C)
Power Supply Voltage, VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17V
Allowed Power Dissipation, PD . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1800mW
Individual Controlling Pins, V14 to 17, V20 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VCC + 0.3V
LED Driving Current, ILED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25mA
Operating Temperature, Topr . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −10° to +65°C
Storage Temperature, Tstg . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −55° to +150°C
Recommended Operating Condition:
Power Supply Voltage, VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9.0 ± 0.5V
Electrical Characteristics: (VCC = 9V, dBs = 0.775Vrms, TA = 25°C)
Parameter
Symbol
Test Conditions
Min
Typ
Max
Unit
SAP Noise Level
VSAP,N
Pin1 Input 5fH (−14.4dBs)
Pin25 Output 15kHz LPF is
attached.
−
−40
−36
dB
SAP Carrier Leakage
CLSAP
Pin1 Input 5fH (−14.4dBs)
Pin25 Output
−
−33
−30
dB
SAP Carrier Detecting
Sensitivity
SCARR
Pin1 Input 5fH
−29.0 −25.0 −21.5
Input level during LED of Pin18
is lighting on
dB
Pin1 Input
SAP 10kHz 100% (−14.4dBs)
Pin25 Output 15kHz lPF is
attached
dB
SAP Frequency
Characteristics
10kHz
ASAP
−4.0
−1.5
2.0
Electrical Characteristics (Cont’d): (VCC = 9V, dBs = 0.775Vrms, TA = 25°C)
Parameter
SAP Output Level
SAP Distortion Ratio
Symbol
Test Conditions
Min
Typ
Max
Unit
VSAP
Pin1 Input
SAP 1kHz 100% (−14.4dBs)
Pin25 Output 15kHz LPF is
attached
−0.8
−0.1
0.6
dB
THDSAP
Pin1 Input
SAP 1kHz 100% (−14.4dBs)
Pin25 Output 15kHz LPF is
attached
−
4.0
8.0
%
SAP BPF Frequency
Characteristics 5fH
A BPF 5fH
Pin1 Input 5fH (−14.4dBs)
Pin6 Output
−16
−13.5 −12.5
dB
SAP BPF Frequency
Characteristics 3fH
A BPF 3fH
Pin1 Input 3fH (−14.4dBs)
Pin6 Output
−
−32.5 −29.5
dB
−
−31.6 −29.5
dB
SAP BPF Frequency
Characteristics 6.5fH
SAP Detecting
Characteristics
A BPF 6.5fH Pin1 Input 6.5fH (−14.4dBs)
Pin6 Output
VSAP FM
Pin8 Input
63.37kHz (−14.4dBs)
93.67kHz (−14.4dBs)
Pin25 Output
100
110
118
mV/kHz
SAP Muting Attenutation
Amount
ATSAP
Pin8 Input
SAP 1kHz 100% (−14.4dBs)
Pin25 Output
−
−68
−65
dB
MONAURAL Noise Level
VST NM
Non−input
Pin23 Output 15kHz LPF is
attached
−
−75
−70
dB
STEREO Noise Level
VST NS
Pin1 fH (−24dBs)
Pin40 to Pin41 −6dB ATT
Pin24 Output 15kHz LPF is
attached
−
−70
−66
dB
MAIN Output Level
VMAIN
Pin1 Input 1kHz (−10dBs)
75µs de−emphasis is attached
Pin23 Output 15kHz LPF is
attached
−5.6
−5.0
−4.6
dB
SUB Detecting Level
VSUB
Pin1 Input SUB 1kHz 100%
Pin40 to Pin41 −6dB ATT
Pin24 Output 15kHz LPF is
attached
−12
−
−9
dB
THDMONO
Pin1 Input 1kHz (−10dBs)
Pin23 Output 15kHz LPF is
attached
−
0.25
0.50
%
STEREO Distortion
THDSTE
Pin1 Input SUB 1kHz 100%
Pin24 Output 15kHz LPF is
attached
−
0.75
1.20
%
Pilot Cancel (L + R)
PCL + R
Pin1 Input fH (−24dBs)
75µs de−emphasis is attached
Pin23 Output fH BPF is attached
−
−57.0 −51.5
Pilot Cancel (L − R)
PCL − R
Pin1 Input fH (−24dBs)
Pin40 to Pin41 −6dB ATT
Pin24 Output fH BPF is attached
−
MONAURAL Distortion
Ratio
−41
−35
dB
dB
Electrical Characteristics (Cont’d): (VCC = 9V, dBs = 0.775Vrms, TA = 25°C)
Parameter
Symbol
Test Conditions
Min
Typ
Max
Unit
MAIN Balance
Between Channels
CBMAIN
Pin34 Input fH (−18dBs)
Input 1kHz (−4dBs) to Pin28 and
find the output level difference
between Pin22 and Pin23 by
measuring the outputs of Pin22
and Pin23 independently
−0.3
0
0.3
dB
SUB Balance
Between Channels
CBSUB
Input 1kHz (−4dBs) to Pin27 and
find the output level difference
between Pin22 and Pin23 by
measuring the outputs of Pin22
and Pin23 independently. The
above applicable to Pin28 except that non−input to Pin28.
−0.3
0
0.3
dB
Separation Check 1kHz
SEP1k
Pin1 input L Ch 100% DSB 1kHz
Measure phase difference between the outputs of Pin24 and
Pin23.
46
60
−
dB
Crosstalk
(L − R) ↔ (SAP)
CTL−R SAP
Pin26 and Pin41 Input 1kHz
(−4dBs)
Pin24 Output +1kHz BPF
−
−80
−67
dB
Crosstalk L ↔ SAP
CTLSAP
Pin27 and Pin28 Output 1kHz
(−4dBs)
Pin23 Output + 1kHz BPF
−
−80
−74
dB
Crosstalk R ↔ SAP
CTRSAP
Pin27 and Pin28 Input 1kHz
(−4dBs)
Pin22 Output + 1kHz BPF
−
−80
−74
dB
−
−45
−36
dB
−5.2
−4.3
−2.8
dB
−
−52
−43
dB
−6.5
−5.3
−4.0
dB
Stereo LPF Frequency
Characteristics (6fH)
ALP1 6fH
Pin1 Input 6fH (−10dBs)
Pin37 Output
(L + R) LPF Frequency
Characteristics
(12kHz)
ALP2 12k
Pin34 Input 12kHz (−4dBs)
Pin29 Output
(L + R) LPF Frequency
Characteristics (2fH)
ALP2 2fH
Pin34 Input 2fH (−4dBs)
Pin29 Output
L − R LPF Frequency
Characteristics
(12kHz)
ALP3 12k
Pin26 Input 12kHz (−4dBs)
Pin24 Output
L − R LPF Frequency
Characteristics (2fH)
ALP3 2fH
Pin26 Input 2fH (−4dBs)
Pin24 Output
−
−52
−43
dB
Stereo Capture Range
LOW
CRLO
Pin34 Input fH vicinity (−18dBs)
Measure the input frequency
when the LED of Pin19 goes on
and off by changing the burst
signal frequency
−
−
14.95
kHz
Stereo Capture Range
HIGH
CRHI
Pin35 and Pin36, 1µF and 4.7µF 16.52
560Ω
−
−
kHz
Parameter
Symbol
During Forced Monaural
Crosstalk (L)
CTL
During Forced Monaural
Crosstalk (R)
CTR
Test Conditions
Min
Typ
Max
Unit
Pin27 Input 1kHz (−4dBs)
Pin23 Output +1kHz BPF
−
−80
−74
dB
Pin27 Input 1kHz (−4dBs)
Pin22 Output +1kHz BPF
−
−80
−74
dB
Electrical Characteristics (Cont’d): (VCC = 9V, dBs = 0.775Vrms, TA = 25°C)
Parameter
Symbol
Test Conditions
Pin27 Input 1kHz (−4dBs)
Pin22 and Pin23 Output
+15kHz LPF
Min
Typ
Max
Unit
−
−80
−74
dB
Muting SW V15
High Muting
Attenuation Amount
(L) (R)
ATST L
DC Offset Voltage while
Muting and Stereo
are turned on
VOMU ST
During no−input
−50
5
50
mV
DC Offset Voltage while
Muting and SAP
are turned on
VOMU SAP
During no−input
−120
−20
120
mV
DC Offset Voltage while
SAP and Monaural
are turned on
VOSAP MO
During no−input
−50
0
50
mV
DC Offset Voltage while
SAP and Stereo
are turned on
VOSAP ST
During no−input
−120
0
120
mV
DC Offset Voltage while
Stereo and Monaural
are turned on
VOST MO
During no−input
−120
−20
120
mV
25
36
48
mA
Circuit Current
ICC
V14, V15, V16 and V17
Controlling Voltage
(L)
VX L
GND
−
1.0
V
V14, V15, V16, and V17
Controlling Voltage
(H)
VX H
2.5
−
VCC
V
V13 and V20 Controlling
Voltage (L)
VZ L
GND
−
1.0
V
V13 and V20 Controlling
Voltage (M)
VZ M
2.5
−
5.5
V
V13 and V20 Controlling
Voltage (H)
VZ H
8.0
−
VCC
V
Pin30 and Pin31 10µF fH
level is variable
12
26
39
mVrms
Pin9 DC
6.7
−
−
V
Stereo Discriminating
Level
Regulator Voltage
STE Vth
VREG
Value of inflowing current into
Pin42
Note 1. This device is for REPLACEMENT ONLY! No design information is available.
Pin Connection Diagram
MPX Input
1
42 VCC
N.C.
2
41 (L+R) Switch Input
Stereo Filter Adjust
3
40 (L+R) Detector Output
SAP Filter Adjust
4
39 TP
Bias
5
38 N.C.
SAP BPF Output
6
37 Stereo LPF Output
N.C.
7
36 Phase Det (+)
SAP Detector Input
8
35 Phase Det (−)
Reg Out 6.7V
9
34 Stereo Input
SAP VCO Adjust 10
33 Stereo GND
Car Det 11
32 ST VCO Adjust
SAP GND 12
31 Pilot Det (+)
SAP SQU Inhibit 13
30 Pilot Det (−)
SAP Mute 14
29 L+R Output
Mute 15
28 Matrix L+R Input
MS 1 16
27 Matrix L+R/SAP Input
MS 0 17
26 SAP Switch Input
SAP Ind Drive 18
Stereo Ind Drive 19
25 SAP Det Output
24 (L+R) SAP Output
Forced Monaural 20
23 Line Output L
LED GND 21
22 Line Output R
42
22
1
21
1.503 (38.2) Max
.519 (13.2)
.217
(5.5)
.070 (1.78)
.119 (3.0)
.600 (15.24)