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MC1496, MC1496B Balanced Modulators/ Demodulators
These devices were designed for use where the output voltage is a product of an input voltage (signal) and a switching function (carrier). Typical applications include suppressed carrier and amplitude modulation, synchronous detection, FM detection, phase detection, and chopper applications. See ON Semiconductor Application Note AN531 for additional design information. · Excellent Carrier Suppression 65 dB typ @ 0.5 MHz 50 dB typ @ 10 MHz · Adjustable Gain and Signal Handling · Balanced Inputs and Outputs · High Common Mode Rejection 85 dB typical
14 This device contains 8 active transistors. 1
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SO14 D SUFFIX CASE 751A
14 1
PDIP14 P SUFFIX CASE 646
PIN CONNECTIONS
Signal Input 1 14 VEE 13 N/C 12 Output 11 N/C 10 Carrier Input 9 N/C 8 Input Carrier
Figure 1. Suppressed Carrier Output Waveform
Gain Adjust 2 Gain Adjust 3 Signal Input 4 Bias 5
IC = 500 kHz, IS = 1.0 kHz
Output 6 N/C 7
0 IC = 500 kHz IS = 1.0 kHz Log Scale Id 20
ORDERING INFORMATION
See detailed ordering and shipping information in the package dimensions section on page 11 of this data sheet.
Figure 2. Suppressed Carrier Spectrum DEVICE MARKING INFORMATION
See general marking information in the device marking section on page 11 of this data sheet. 499 kHz 500 kHz 501 kHz 10 8.0 Linear Scale 6.0 4.0 2.0 0 IC = 500 kHz IS = 1.0 kHz IC = 500 kHz IS = 1.0 kHz
40 60
Figure 3. Amplitude Modulation Output Waveform
499 kHz
500 kHz
501 kHz
Figure 4. AmplitudeModulation Spectrum
1 Publication Order Number: MC1496/D
© Semiconductor Components Industries, LLC, 2001
September, 2001 Rev. 6
MC1496, MC1496B
MAXIMUM RATINGS (TA = 25°C, unless otherwise noted.)
Rating Applied Voltage (V6V8, V10V1, V12V8, V12V10, V8V4, V8V1, V10V4, V6V10, V2V5, V3V5) Differential Input Signal Maximum Bias Current Thermal Resistance, JunctiontoAir Plastic Dual InLine Package Operating Ambient Temperature Range Storage Temperature Range NOTE: ESD data available upon request. MC1496 MC1496B Symbol V V8 V10 V4 V1 I5 RJA TA Tstg Value 30 +5.0 ±(5+I5Re) 10 100 0 to +70 40 to +125 65 to +150 Unit Vdc Vdc mA °C/W °C °C
ELECTRICAL CHARACTERISTICS (VCC = 12 Vdc, VEE = 8.0 Vdc, I5 = 1.0 mAdc, RL = 3.9 k, Re = 1.0 k, TA = Tlow to Thigh, all input and output characteristics are singleended, unless otherwise noted.) (Note 1)
Characteristic Carrier Feedthrough VC = 60 mVrms sine wave and offset adjusted to zero VC = 300 mVpp square wave: offset adjusted to zero offset not adjusted Carrier Suppression fS = 10 kHz, 300 mVrms fC = 500 kHz, 60 mVrms sine wave fC = 10 MHz, 60 mVrms sine wave Transadmittance Bandwidth (Magnitude) (RL = 50 ) Carrier Input Port, VC = 60 mVrms sine wave fS = 1.0 kHz, 300 mVrms sine wave Signal Input Port, VS = 300 mVrms sine wave |VC| = 0.5 Vdc Signal Gain (VS = 100 mVrms, f = 1.0 kHz; |VC|= 0.5 Vdc) SingleEnded Input Impedance, Signal Port, f = 5.0 MHz Parallel Input Resistance Parallel Input Capacitance SingleEnded Output Impedance, f = 10 MHz Parallel Output Resistance Parallel Output Capacitance Input Bias Current I + I1 ) I4 ; I + I8 ) I10 bS bC 2 2 Input Offset Current IioS = I1I4; IioC = I8I10 Average Temperature Coefficient of Input Offset Current (TA = 55°C to +125°C) Output Offset Current (I6I9) Average Temperature Coefficient of Output Offset Current (TA = 55°C to +125°C) CommonMode Input Swing, Signal Port, fS = 1.0 kHz CommonMode Gain, Signal Port, fS = 1.0 kHz, |VC|= 0.5 Vdc CommonMode Quiescent Output Voltage (Pin 6 or Pin 9) Differential Output Voltage Swing Capability Power Supply Current I6 +I12 Power Supply Current I14 DC Power Dissipation 1. Tlow = 0°C for MC1496 = 40°C for MC1496B Thigh = +70°C for MC1496 = +125°C for MC1496B fC = 1.0 kHz fC = 10 MHz fC = 1.0 kHz fC = 1.0 kHz 5 2 VCS 40 8 8 BW3dB 10 6 3 rip cip 6 rop coo 7 IbS IbC 7 7 7 7 9 9 10 10 7 7 4 6 5 IioS IioC TCIio Ioo TCIoo CMV ACM Vout Vout ICC IEE PD 12 12 0.7 0.7 2.0 14 90 5.0 85 8.0 8.0 2.0 3.0 33 30 30 7.0 7.0 80 4.0 5.0 µA nA/°C µA nA/°C Vpp dB Vpp Vpp mAdc mW 40 5.0 k pF µ µA 200 2.0 k pF AVS 2.5 300 80 3.5 V/V 65 50 Fig. 5 Note 1 Symbol VCFT 40 140 0.04 20 mVrms 0.4 200 dB k MHz Min Typ Max Unit µVrms
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MC1496, MC1496B
GENERAL OPERATING INFORMATION
Carrier Feedthrough
Carrier feedthrough is defined as the output voltage at carrier frequency with only the carrier applied (signal voltage = 0). Carrier null is achieved by balancing the currents in the differential amplifier by means of a bias trim potentiometer (R1 of Figure 5).
Carrier Suppression
Note that in the test circuit of Figure 10, VS corresponds to a maximum value of 1.0 V peak.
Common Mode Swing
Carrier suppression is defined as the ratio of each sideband output to carrier output for the carrier and signal voltage levels specified. Carrier suppression is very dependent on carrier input level, as shown in Figure 22. A low value of the carrier does not fully switch the upper switching devices, and results in lower signal gain, hence lower carrier suppression. A higher than optimum carrier level results in unnecessary device and circuit carrier feedthrough, which again degenerates the suppression figure. The MC1496 has been characterized with a 60 mVrms sinewave carrier input signal. This level provides optimum carrier suppression at carrier frequencies in the vicinity of 500 kHz, and is generally recommended for balanced modulator applications. Carrier feedthrough is independent of signal level, VS. Thus carrier suppression can be maximized by operating with large signal levels. However, a linear operating mode must be maintained in the signalinput transistor pair or harmonics of the modulating signal will be generated and appear in the device output as spurious sidebands of the suppressed carrier. This requirement places an upper limit on inputsignal amplitude (see Figure 20). Note also that an optimum carrier level is recommended in Figure 22 for good carrier suppression and minimum spurious sideband generation. At higher frequencies circuit layout is very important in order to minimize carrier feedthrough. Shielding may be necessary in order to prevent capacitive coupling between the carrier input leads and the output leads.
Signal Gain and Maximum Input Level
The commonmode swing is the voltage which may be applied to both bases of the signal differential amplifier, without saturating the current sources or without saturating the differential amplifier itself by swinging it into the upper switching devices. This swing is variable depending on the particular circuit and biasing conditions chosen.
Power Dissipation
Power dissipation, PD, within the integrated circuit package should be calculated as the summation of the voltagecurrent products at each port, i.e. assuming V12 = V6, I5 = I6 = I12 and ignoring base current, PD = 2 I5 (V6 V14) + I5)V5 V14 where subscripts refer to pin numbers.
Design Equations
The following is a partial list of design equations needed to operate the circuit with other supply voltages and input conditions. A. Operating Current The internal bias currents are set by the conditions at Pin 5. Assume: I5 = I6 = I12, IBttIC for all transistors then :
where: R5 is the resistor between V * *f *500 W where: Pin 5 and ground I5 where: = 0.75 at TA = +25°C
R5+
The MC1496 has been characterized for the condition I5 = 1.0 mA and is the generally recommended value. B. CommonMode Quiescent Output Voltage
V6 = V12 = V+ I5 RL Biasing
Signal gain (singleended) at low frequencies is defined as the voltage gain,
A VS + R Vo L + where r e + 26 mV R e)2r e V I5(mA) S
A constant dc potential is applied to the carrier input terminals to fully switch two of the upper transistors "on" and two transistors "off" (VC = 0.5 Vdc). This in effect forms a cascode differential amplifier. Linear operation requires that the signal input be below a critical value determined by RE and the bias current I5.
VS p I5 RE (Volts peak)
The MC1496 requires three dc bias voltage levels which must be set externally. Guidelines for setting up these three levels include maintaining at least 2.0 V collectorbase bias on all transistors while not exceeding the voltages given in the absolute maximum rating table; 30 Vdc w [(V6, V12) (V8, V10)] w 2 Vdc 30 Vdc w [(V8, V10) (V1, V4)] w 2.7 Vdc 30 Vdc w [(V1, V4) (V5)] w 2.7 Vdc The foregoing conditions are based on the following approximations:
V6 = V12, V8 = V10, V1 = V4
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MC1496, MC1496B
Bias currents flowing into Pins 1, 4, 8 and 10 are transistor base currents and can normally be neglected if external bias dividers are designed to carry 1.0 mA or more.
Transadmittance Bandwidth
in both the carrier and modulating signal inputs with a singleended output connection.
Negative Supply
Carrier transadmittance bandwidth is the 3.0 dB bandwidth of the device forward transadmittance as defined by:
g21C+ i o (each sideband) v s (signal)
VEE should be dc only. The insertion of an RF choke in series with VEE can enhance the stability of the internal current sources.
Signal Port Stability
Vo + 0
Signal transadmittance bandwidth is the 3.0 dB bandwidth of the device forward transadmittance as defined by:
i o (signal) g21S+ v (signal) s
Vc + 0.5 Vdc, Vo + 0
Under certain values of driving source impedance, oscillation may occur. In this event, an RC suppression network should be connected directly to each input using short leads. This will reduce the Q of the sourcetuned circuits that cause the oscillation.
Signal Input (Pins 1 and 4) 510 10 pF
Coupling and Bypass Capacitors
Capacitors C1 and C2 (Figure 5) should be selected for a reactance of less than 5.0 at the carrier frequency.
Output Signal
The output signal is taken from Pins 6 and 12 either balanced or singleended. Figure 11 shows the output levels of each of the two output sidebands resulting from variations
An alternate method for lowfrequency applications is to insert a 1.0 k resistor in series with the input (Pins 1, 4). In this case input current drift may cause serious degradation of carrier suppression.
TEST CIRCUITS
1.0 k 51 C1 0.1 µF 1.0 k Re 8 10 1 4 51 2 1.0 k 3 RL 3.9 k I9 I6 MC1496 14 I10 V-8.0 Vdc VEE VCC 12 Vdc 1.0 k I7 I8 I1 I4 8 10 1 4 Re = 1.0 k 2 MC1496 14 I10 -8.0 Vdc VEE 5 6.8 k 3 I6 6 12 I9 2.0 k Carrier Input 0.1 µF VC VS Modulating Signal Input 10 k I5 5 6.8 k
NOTE:
VCC 12 Vdc RL 3.9 k +Vo -Vo Zin 0.5 V 8 + - 10 1 4 2
Re = 1.0 k 3 MC1496 14 5 6.8 k -8.0 Vdc
Shielding of input and output leads may be needed to properly perform these tests.
C2 Carrier Input 0.1 µF VC VS Modulating Signal Input 10 k R1
6 12
6 12
+Vo Zout -Vo
10 k 51 50 k Carrier Null
Figure 5. Carrier Rejection and Suppression
Figure 6. InputOutput Impedance
1.0 k 51 0.1 µF 8 10 1 4 10 k 50 k Carrier Null V-8.0 Vdc VEE 51 51 1.0 k Re 2 1.0 k 3 6 12 14 5 6.8 k VCC 12 Vdc 2.0 k 50 50 0.01 µF +Vo -Vo
1.0 k
MC1496
Figure 7. Bias and Offset Currents
Figure 8. Transconductance Bandwidth
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MC1496, MC1496B
VCC 12 Vdc 1.0 k 1.0 k VS Re = 1.0 k 3.9 k 3.9 k 1.0 k +Vo -Vo VS 50 V A + 20 log o CM V S 1.0 k 8 + - 10 1 4 0.5 V 2 MC1496 14 I5 = 1.0 mA -8.0 Vdc VEE 5 6.8 k Re = 1.0 k 3 3.9 k 6 12 3.9 k +Vo -Vo 3 0.5 V 8 2 + - 10 1 MC1496 6 4 12 14 50 -8.0 Vdc VEE 5 6.8 k VCC 12 Vdc
Figure 9. Common Mode Gain
Figure 10. Signal Gain and Output Swing
TYPICAL CHARACTERISTICS
VO , OUTPUT AMPLITUDE OF EACH SIDEBAND (Vrms) Typical characteristics were obtained with circuit shown in Figure 5, fC = 500 kHz (sine wave), VC = 60 mVrms, fS = 1.0 kHz, VS = 300 mVrms, TA = 25°C, unless otherwise noted. 1.0 M r ip, PARALLEL INPUT RESISTANCE (k ) 500 +rip -rip
2.0
1.6 1.2 0.8 0.4 0 Signal Input = 600 mV 400 mV 300 mV 200 mV 100 mV 0 50 100 150 VC, CARRIER LEVEL (mVrms) 200
100 50 10 5.0 1.0 1.0
5.0 10 f, FREQUENCY (MHz)
50
100
Figure 11. Sideband Output versus Carrier Levels
cip , PARALLEL INPUT CAPACITANCE (pF) 140 120 100 80 60 40 20 0 0
Figure 12. SignalPort ParallelEquivalent Input Resistance versus Frequency
14 12 10 rop cop 8.0 6.0 4.0 2.0 1.0 10 f, FREQUENCY (MHz) 0 100 cop, PARALLEL OUTPUT CAPACITANCE (pF)
4.0 3.0 2.0 1.0 0 1.0
2.0
20 10 5.0 f, FREQUENCY (MHz)
50
100
Figure 13. SignalPort ParallelEquivalent Input Capacitance versus Frequency
rop , PARALLEL OUTPUT RESISTANCE (k )
5.0
Figure 14. SingleEnded Output Impedance versus Frequency
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MC1496, MC1496B
TYPICAL CHARACTERISTICS (continued)
Typical characteristics were obtained with circuit shown in Figure 5, fC = 500 kHz (sine wave), VC = 60 mVrms, fS = 1.0 kHz, VS = 300 mVrms, TA = 25°C, unless otherwise noted.
21, TRANSADMITTANCE (mmho)
VCS, CARRIER SUPPRESION (dB)
1.0 0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0
0 Signal Port 10 20 30 40 50 60 70 -75 -50 -25 0 25 50 75 100 125 150 175 MC1496 (70°C)
Side Band Sideband Transadmittance I out (Each Sideband) g21 + V out + 0 V (Signal) in
0.1
Signal Port Transadmittance I g21 + out V out + 0 |V | + 0.5 Vdc C V in 10 1.0 100 fC, CARRIER FREQUENCY (MHz)
1000
TA, AMBIENT TEMPERATURE (°C)
Figure 15. Sideband and Signal Port Transadmittances versus Frequency
Figure 16. Carrier Suppression versus Temperature
10 0 -10 -20 -30 0.01 |VC| = 0.5 Vdc RL = 3.9 k (Standard Re = 1.0 k Test Circuit) RL = 3.9 k Re = 2.0 k RL = 500 Re = 1.0 k R
RL = 3.9 k Re = 500
SUPPRESSION BELOW EACH FUNDAMENTAL CARRIER SIDEBAND (dB)
AVS , SINGLE ENDED VOLTAGE GAIN (dB)
20
0 10 20 30 40 50 60 70 0.05 0.1 fC 2fC
L A + V R e ) 2r e 0.1 1.0 f, FREQUENCY (MHz) 10 100
3fC 50
0.5 1.0 5.0 10 fC, CARRIER FREQUENCY (MHz)
Figure 17. SignalPort Frequency Response
Figure 18. Carrier Suppression versus Frequency
VCFT , CARRIER OUTPUT VOLTAGE (mVrms)
SUPPRESSION BELOW EACH FUNDAMENTAL CARRIER SIDEBAND (dB)
10
0 10 20 30 40 50 60 70 80 0 200 400 600 VS, INPUT SIGNAL AMPLITUDE (mVrms) 800 fC ± 3fS fC ± 2fS
1.0
0.1
0.01 0.05
0.1
0.5 1.0 5.0 10 fC, CARRIER FREQUENCY (MHz)
50
Figure 19. Carrier Feedthrough versus Frequency
Figure 20. Sideband Harmonic Suppression versus Input Signal Level
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MC1496, MC1496B
SUPPRESSION BELOW EACH FUNDAMENTAL CARRIER SIDEBAND (dB) 0 10 20 30 40 50 60 70 0.05 0.1 0.5 1.0 5.0 10 fC, CARRIER FREQUENCY (MHz) 50 2fC ± fS 2fC ± 2fS 3fC ± fS V CS , CARRIER SUPPRESSION (dB) 0 10 20 30 40 50 60 70 0 100 200 300 400 VC, CARRIER INPUT LEVEL (mVrms) 500 fC = 500 kHz fC = 10 MHz
Figure 21. Suppression of Carrier Harmonic Sidebands versus Carrier Frequency
Figure 22. Carrier Suppression versus Carrier Input Level
OPERATIONS INFORMATION The MC1496, a monolithic balanced modulator circuit, is shown in Figure 23. This circuit consists of an upper quad differential amplifier driven by a standard differential amplifier with dual current sources. The output collectors are crosscoupled so that fullwave balanced multiplication of the two input voltages occurs. That is, the output signal is a constant times the product of the two input signals. Mathematical analysis of linear ac signal multiplication indicates that the output spectrum will consist of only the sum and difference of the two input frequencies. Thus, the device may be used as a balanced modulator, doubly balanced mixer, product detector, frequency doubler, and other applications requiring these particular output signal characteristics. The lower differential amplifier has its emitters connected to the package pins so that an external emitter resistance may be used. Also, external load resistors are employed at the device output.
Signal Levels
The upper quad differential amplifier may be operated either in a linear or a saturated mode. The lower differential amplifier is operated in a linear mode for most applications. For lowlevel operation at both input ports, the output signal will contain sum and difference frequency
(-) 12 (+) 6 10 (-) Carrier V C Input 8 (+) Signal V S 1 (+) Input Bias 5 VEE 14 500 500 500 4 (-) 2 3 Gain Adjust Vo, Output
components and have an amplitude which is a function of the product of the input signal amplitudes. For highlevel operation at the carrier input port and linear operation at the modulating signal port, the output signal will contain sum and difference frequency components of the modulating signal frequency and the fundamental and odd harmonics of the carrier frequency. The output amplitude will be a constant times the modulating signal amplitude. Any amplitude variations in the carrier signal will not appear in the output. The linear signal handling capabilities of a differential amplifier are well defined. With no emitter degeneration, the maximum input voltage for linear operation is approximately 25 mV peak. Since the upper differential amplifier has its emitters internally connected, this voltage applies to the carrier input port for all conditions. Since the lower differential amplifier has provisions for an external emitter resistance, its linear signal handling range may be adjusted by the user. The maximum input voltage for linear operation may be approximated from the following expression:
V = (I5) (RE) volts peak.
This expression may be used to compute the minimum value of RE for a given input voltage amplitude.
1.0 k 51 V 0.1 µF Carrier C Input VS Modulating Signal 10 k Input
1.0 k 0.1 µF 8 10 1 4 51 51 2 Re 1.0 k 3 RL 3.9 k 6 MC1496 12 14 I5 -8.0 Vdc VEE 5 6.8 k
12 Vdc RL 3.9 k +Vo -Vo
10 k 50 k Carrier Null
(Pin numbers per G package)
Figure 23. Circuit Schematic http://onsemi.com
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Figure 24. Typical Modulator Circuit
MC1496, MC1496B
Carrier Input Signal (VC) Lowlevel dc Approximate Voltage Gain R V L C 2(R ) 2r e) KT q E R L R ) 2r e E R V (rms) L C KT (R ) 2r ) 2 2 q e E 0.637 R L R ) 2r e E Output Signal Frequency(s)
fM
Highlevel dc
fM
Lowlevel ac
fC ± fM
Highlevel ac
fC ± fM, 3fC ± fM, 5fC ± fM, . . .
2. Lowlevel Modulating Signal, VM, assumed in all cases. VC is Carrier Input Voltage. 3. When the output signal contains multiple frequencies, the gain expression given is for the output amplitude ofeach of the two desired outputs, fC + fM and fC fM. 4. All gain expressions are for a singleended output. For a differential output connection, multiply each expression by two. 5. RL = Load resistance. 6. RE = Emitter resistance between Pins 2 and 3. 7. re = Transistor dynamic emitter resistance, at 25°C;
re [
8. K = Boltzmanns Constant, T = temperature in degrees Kelvin, q = the charge on an electron.
KT [ 26mV at room temperature q
26mV I5(mA)
Figure 25. Voltage Gain and Output Frequencies
The gain from the modulating signal input port to the output is the MC1496 gain parameter which is most often of interest to the designer. This gain has significance only when the lower differential amplifier is operated in a linear mode, but this includes most applications of the device. As previously mentioned, the upper quad differential amplifier may be operated either in a linear or a saturated mode. Approximate gain expressions have been developed for the MC1496 for a lowlevel modulating signal input and the following carrier input conditions: 1) Lowlevel dc 2) Highlevel dc 3) Lowlevel ac 4) Highlevel ac These gains are summarized in Figure NO TAG, along with the frequency components contained in the output signal. APPLICATIONS INFORMATION Double sideband suppressed carrier modulation is the basic application of the MC1496. The suggested circuit for this application is shown on the front page of this data sheet. In some applications, it may be necessary to operate the MC1496 with a single dc supply voltage instead of dual supplies. Figure 26 shows a balanced modulator designed for operation with a single 12 Vdc supply. Performance of this circuit is similar to that of the dual supply modulator.
AM Modulator
All that is required to shift from suppressed carrier to AM operation is to adjust the carrier null potentiometer for the proper amount of carrier insertion in the output signal. However, the suppressed carrier null circuitry as shown in Figure 27 does not have sufficient adjustment range. Therefore, the modulator may be modified for AM operation by changing two resistor values in the null circuit as shown in Figure 28.
Product Detector
The circuit shown in Figure 27 may be used as an amplitude modulator with a minor modification.
The MC1496 makes an excellent SSB product detector (see Figure 29). This product detector has a sensitivity of 3.0 microvolts and a dynamic range of 90 dB when operating at an intermediate frequency of 9.0 MHz. The detector is broadband for the entire high frequency range. For operation at very low intermediate frequencies down to 50 kHz the 0.1 µF capacitors on Pins 8 and 10 should be increased to 1.0 µF. Also, the output filter at Pin 12 can be tailored to a specific intermediate frequency and audio amplifier input impedance. As in all applications of the MC1496, the emitter resistance between Pins 2 and 3 may be increased or decreased to adjust circuit gain, sensitivity, and dynamic range. This circuit may also be used as an AM detector by introducing carrier signal at the carrier input and an AM signal at the SSB input. The carrier signal may be derived from the intermediate frequency signal or generated locally. The carrier signal may be introduced with or without modulation, provided its level
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MC1496, MC1496B
is sufficiently high to saturate the upper quad differential amplifier. If the carrier signal is modulated, a 300 mVrms input level is recommended.
Doubly Balanced Mixer
Figures 31 and 32 show a broadband frequency doubler and a tuned output very high frequency (VHF) doubler, respectively.
Phase Detection and FM Detection
The MC1496 may be used as a doubly balanced mixer with either broadband or tuned narrow band input and output networks. The local oscillator signal is introduced at the carrier input port with a recommended amplitude of 100 mVrms. Figure 30 shows a mixer with a broadband input and a tuned output.
Frequency Doubler
The MC1496 will operate as a frequency doubler by introducing the same frequency at both input ports.
The MC1496 will function as a phase detector. Highlevel input signals are introduced at both inputs. When both inputs are at the same frequency the MC1496 will deliver an output which is a function of the phase difference between the two input signals. An FM detector may be constructed by using the phase detector principle. A tuned circuit is added at one of the inputs to cause the two input signals to vary in phase as a function of frequency. The MC1496 will then provide an output which is a function of the input signal frequency.
TYPICAL APPLICATIONS
VCC 12 Vdc 3.0 k 6 MC1496 5 12 10 k 3.0 k DSB 0.1 µF Output 51 VC 0.1 µF Carrier Input VS Modulating 10 k Signal Input 1.0 k 1.0 k 0.1 µF 2 8 10 1 4 51 51 14 I5 VEE -8.0 Vdc Re 1.0 k RL 3 3.9 k 6 MC1496 5 12 -Vo VCC 12 Vdc RL 3.9 k +Vo
1.0 k +
820 0.1 µF 0.1 µF 51 8 10 1 4
1.3 k 2 1.0 k
Carrier Input 60 mVrms
25 µF 15 V
3
Modulating -
+
Signal Input 10 µF 300 mVrms 15 V Carrier Null 50 k 10 k 10 k 100
25 µF 14 15 V + 100
10 k 50 k R1 Carrier Null
6.8 k
Figure 26. Balanced Modulator (12 Vdc Single Supply)
Figure 27. Balanced ModulatorDemodulator
1.0 k 51 VC 0.1 µF Carrier Input VS Modulating Signal 750 Input
1.0 k RL 0.1 µF 2 Re 1.0 k 3 3.9 k 8 6 10 1 MC1496 4 12 51 51 14 5 15 6.8 k VEE -8.0 Vdc
VCC 12 Vdc RL 3.9 k 1.0 k
820 0.1 µF 8 0.1 µF 10 1 0.1 µF 1.0 k 4 1.0 k 0.1 µF 51 2
1.3 k 100 3.0 k 6 MC1496 14 5 12 10 k
VCC 12 Vdc 3.0 k 0.005 µF AF 1.0 k 1.0 µFOutput RLq 10 k 0.005 0.005 µF µF
3
+Vo Carrier Input 300 mVrms -Vo SSB Input
750 50 k
Carrier Adjust
Figure 28. AM Modulator Circuit
Figure 29. Product Detector (12 Vdc Single Supply)
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MC1496, MC1496B
VCC +8.0 Vdc RFC 100 µH 6 MC1496 12 5 5.0-80 pF 6.8 k VEE -8.0 Vdc 0.001 µF 9.5 µF L1 9.0 MHz Output RL = 50 1.0 k VCC 12 Vdc + 1.0 k C2 100 100 µF 25 Vdc 8 10 MC1496 12 14 5 6.8 k VEE -8.0 Vdc I5 1.0 k 3.9 k 3.9 k 6 Output
1.0 k 0.001 µF Local Oscillator Input 100 mVrms RF Input 51 8 10 0.001 µF 1 51 10 k 4 2
1.0 k 3 0.01 µF
2
3
100 µF - C2+ Input 15 Vdc Max 100 µF 15 Vdc 15 mVrms 1 4 10 k 50 k 10 k 100 100
10 k 51 50 k Null Adjust
14
90-480 pF
L1 = 44 Turns AWG No. 28 Enameled Wire, Wound on Micrometals Type 446 Toroid Core.
Balance
Figure 30. Doubly Balanced Mixer (Broadband Inputs, 9.0 MHz Tuned Output)
Figure 31. LowFrequency Doubler
1.0 k
1.0 k 0.001 µF 8 10 1 4 0.001 µF 2 MC1496 12 3
V+ 18 pF RFC 0.68 µH 6
VCC +8.0 Vdc
100 0.001 µF 150 MHz Input 100 10 k 10 k 50 k Balance
L1 18 nH 1.0-10 pF 1.0-10 pF
300 MHz Output RL = 50
100 14
5
6.8 k VEE -8.0 Vdc
L1 = 1 Turn AWG No. 18 Wire, 7/32 ID
Figure 32. 150 to 300 MHz Doubler
(fC - f S )
AMPLITUDE
(fC + f S )
(2fC + 2f S )
(2fC - 2f S )
(3fC - 2f S ) (3fC - fS )
(2fC - 2f S )
(2fC + 2f S )
(3fC + f S ) (3f C )
Frequency
fC fS fC ± fS Carrier Fundamental Modulating Signal Fundamental Carrier Sidebands
Balanced Modulator Spectrum DEFINITIONS
fC ± nfS Fundamental Carrier Sideband Harmonics Carrier Harmonics nfC nfC ± nfS Carrier Harmonic Sidebands
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(2fC )
(3fC + 2f S )
(fC - 2f S )
(f + 2f ) C S
(fC )
MC1496, MC1496B
ORDERING INFORMATION
Device MC1496D MC1496DR2 MC1496P MC1496P1 MC1496BD MC1496BDR2 MC1496BP Package SO14 SO14 PDIP14 PDIP14 SO14 SO14 PDIP14 Shipping 55 Units/Rail 2500 Tape & Reel 25 Units/Rail 25 Units/Rail 55 Units/Rail 2500 Tape & Reel 25 Units/Rail
MARKING DIAGRAMS
SO14 D SUFFIX CASE 751A 14 MC1496D AWLYWW 1 1 14 MC1496BD AWLYWW 1 14 MC1496P AWLYYWW
PDIP14 P SUFFIX CASE 646 14 MC1496BP AWLYYWW 1
A WL YY, Y WW
= Assembly Location = Wafer Lot = Year = Work Week
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MC1496, MC1496B
PACKAGE DIMENSIONS
A
14 8
SO14 D SUFFIX PLASTIC PACKAGE CASE 751A03 ISSUE F
B P 7 PL 0.25 (0.010)
M
1
7
B
M
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 0.127 (0.005) TOTAL IN EXCESS OF THE D DIMENSION AT MAXIMUM MATERIAL CONDITION.
G C
R X 45 _
F
T
SEATING PLANE
D 14 PL 0.25 (0.010)
M
K T B
S
M A
S
J
DIM A B C D F G J K M P R
MILLIMETERS MIN MAX 8.55 8.75 3.80 4.00 1.35 1.75 0.35 0.49 0.40 1.25 1.27 BSC 0.19 0.25 0.10 0.25 0_ 7_ 5.80 6.20 0.25 0.50
INCHES MIN MAX 0.337 0.344 0.150 0.157 0.054 0.068 0.014 0.019 0.016 0.049 0.050 BSC 0.008 0.009 0.004 0.009 0_ 7_ 0.228 0.244 0.010 0.019
14
8
PDIP8 P SUFFIX PLASTIC PACKAGE CASE 64606 ISSUE M
B
1
7
NOTES: 1. DIMENSIONING AND TOLERANCING PER ANSI Y14.5M, 1982. 2. CONTROLLING DIMENSION: INCH. 3. DIMENSION L TO CENTER OF LEADS WHEN FORMED PARALLEL. 4. DIMENSION B DOES NOT INCLUDE MOLD FLASH. 5. ROUNDED CORNERS OPTIONAL. INCHES MIN MAX 0.715 0.770 0.240 0.260 0.145 0.185 0.015 0.021 0.040 0.070 0.100 BSC 0.052 0.095 0.008 0.015 0.115 0.135 0.290 0.310 --10_ 0.015 0.039 MILLIMETERS MIN MAX 18.16 18.80 6.10 6.60 3.69 4.69 0.38 0.53 1.02 1.78 2.54 BSC 1.32 2.41 0.20 0.38 2.92 3.43 7.37 7.87 --10_ 0.38 1.01
A F N T
SEATING PLANE
L C
K H G D 14 PL 0.13 (0.005)
M
J M
DIM A B C D F G H J K L M N
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MC1496/D