Abstract:
In a noise canceler, a pilot-canceling signal without noise is applied to the inverting input of a subtracter via a first MOS transistor. When a noise signal is present, a pilot signal and noise signal passing through a capacitor are applied to the inverting input port of the subtracter via a second MOS transistor to cancel the noise signal contained in the composite input signal. In the canceler, external noise may be digitally converted and the inverted noise thereof stored in a memory. When a noise signal detector detects the external noise, inverted data corresponding to the external noise is output from the memory. The detector enables an address generator to continuously generate addresses. The memory reads out inverted noise patterns which are converted into analog form and transmitted via a speaker, thereby canceling noises produced by various electrical and electronic appliances as well as nearby automobiles and aircraft.

Description:
BACKGROUND OF THE INVENTION 
     The present invention relates to a noise canceler. 
     All electrical and electronic appliances use electricity represented by voltage and current. The flow of current through wire creates a magnetic field around the wire. Whenever a potential difference exists, electric and electromagnetic fields are produced in the surrounding space that vary over time. Also, when an AC voltage drop occurs, the supply voltage to a circuit is varied, which can cause the circuit to misoperate. Furthermore, these appliances generate electromagnetic waves which may impede the operation of other appliances or may cause their misoperation. Especially, noise produced during the starting of an automobile or the overhead passage of aircraft can result in the interruption of the normal operation of appliances. 
     FIG. 1 shows a conventional noise canceler that comprises a subtracter 1 having: a non-inverting input port (+) and an inverting input port (-); a subtracting signal IN 2  entering via the inverting input port; a signal IN 1  entering via the non-inverting input port; a signal OUT of which noise is canceled; and a capacitor C connected between the two input ports of subtracter 1. 
     A composite signal IN 1  input via the non-inverting input port of subtracter 1 is composed of a low frequency signal and pilot signal IN 2 . The signal input via the inverting input port is a pilot canceling signal which has the same amplitude and phase as those of the pilot signal of the composite signal. 
     Subtracter 1 receives the composite signal IN 2  via the non-inverting input port (+) and the pilot canceling signal IN 2  via the inverting input port (-) so as to output the difference. The difference signal voltage is equal to the voltage applied between the two terminals of capacitor C connected between the non-inverting input port - and inverting input port - of subtracter 1. 
     Capacitor C blocks low frequency components and transmits high frequency components only. When the composite signal IN 1  is applied to the non-inverting input port + of subtracter 1, the low frequency signal is output through the output port of subtracter 1. However, because the high frequency components present at the non-inverting input port (+) are coupled through the capacitor C to the inverting input port (-), any noise signal present in the composite signal IN 1  is also present at the inverting port (-), and the input waveform at the non-inverting input port (+) of the subtracter 1 is the same as that at the inverting input port (-). This is because the input impedance of subtracter 1 is extremely high. Capacitor C, acting as a filter, is effectively an AC short so that, when a noise signal is contained in the composite signal IN 1 , the noise signal is simultaneously applied to both the non-inverting input port (+) and to inverting port (-) of subtracter 1. According to these operations, the noise signal is not passed to the output port of subtracter 1 and the subtracter output is the voltage difference between the direct current components at the non-inverting input port (+) and inverting input port (-). 
     However, in this configuration, the pilot signal and the noise signal of the composite signal IN 1  pass through capacitor C and interfere with the pilot canceling signal applied to the inverting input port (-) of subtracter 1. Performance of the noise canceler is thus reduced. 
     SUMMARY OF THE INVENTION 
     Therefore, it is an object of the present invention to provide an analog noise canceler having an improved signal processing performance by, normally applying only a pilot canceling signal through the inverting input port of a subtracter. When noise is present in the input signal to the analog noise canceler, a signal output from a capacitor is applied thereto. 
     It is another object of the present invention to provide a digital noise canceler for canceling noise by storing data inverted with respect to various normalized noise signals in a memory and reading them out from the memory when a corresponding noise signal is detected. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The above objects and other advantages of the present invention will become more apparent by describing in detail a preferred embodiment thereof with reference to the attached drawings, in which: 
     FIG. 1 is a block diagram of a conventional noise canceler; 
     FIG. 2 is a block diagram of an analog noise canceler according to the present invention; 
     FIG. 3 is a circuit diagram for generating a signal applied to the circuit of FIG. 2; 
     FIGS. 4A-4D are operating timing diagrams for illustrating the operation of the circuit shown in FIG. 3; 
     FIGS. 5a and 5b are block diagrams of digital noise cancelers according to the present invention; and 
     FIG. 6 is a block diagram of a system for recording inverted noise data stored in a memory of digital noise cancelers shown in FIGS. 5a and 5b. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     In FIG. 2, reference numeral 10 represents a subtracter, and reference numerals 20 and 30 represent inverters. Further, reference characters Q 1  and Q 2  indicate NMOS transistors and character C indicates a capacitor. 
     In FIG. 2, the noise canceler 100 of the present invention comprises a subtracter 10 having a non-inverting input port (+) and an inverting input port (-) used for subtracting a second input signal IN 2  from a first input signal IN 1  and outputting an output signal (OUT). A transmission transistor Q 1  connected to the inverting input port (-) of subtracter 10 control is the input of the second input signal IN 2 . A capacitor C and a transmission transistor Q 2  are respectively connected in series between the non-inverting input port (+) and inverting input port (-) of subtracter 10 and control an input of a noise signal (derived from the first input signal IN 1 ) into the inverting input port (-). Inverters 20, 30 invert a third input signal IN 3  so that the inverted third input signal IN 3  controls transmission transistor Q 1 , and so that the double inverted or non-inverted input signal IN 3  controls transmission transistor Q 2 . 
     A composite signal IN 1  input via the non-inverting input port (+) of subtracter 10 consists of a low frequency signal and a pilot signal. The pilot canceling signal input to the inverting input port (-) of subtracter 10 has the same amplitude and phase as those of the pilot signal IN 1  contained in the composite signal. The composite signal IN 1 , which normally does not include a noise signal, is applied to the non-inverting input port (+) of subtracter 10. At this time, the pilot canceling signal is applied to the inverting input port (-) of subtracter 10. 
     When a noise signal is present, the composite signal IN 2  is composed of the low frequency signal, pilot signal and noise signal and is applied to the non-inverting input port (+) of subtracter 10. Here, a filtered derivative of the composite signal IN 1  that has passed through capacitor C is applied to the inverting input port (-) of subtracter 10. The control signal IN 3  determines which signal is applied as the pilot canceling signal: either the input signal IN 2  passing through transistor Q 1  or the signal passing through capacitor C and transistor Q 2 . 
     FIG. 3 shows a circuit diagram for producing control signal IN 3  illustrated in FIG. 2. Here, reference numeral 50 denotes a control signal generating circuit, reference numeral 51 indicates a comparator, reference numeral 52 indicates an amplifier, the letter R indicates a resistor, D denotes a diode, and V ref  indicates a reference voltage source. 
     The circuit of FIG. 3 comprises a comparator 51 having a non-inverting input port (+) for receiving a signal P, an inverting port (-) for receiving a signal Q, an amplifier 52 for receiving and amplifying the output signal of comparator 51, a resistor R connected between the output of amplifier 52 and the output port of the control signal generating circuit, a diode D whose anode is also connected to the output port of the control signal generating circuit, and a reference voltage source V ref  connected between the cathode of diode D and ground. 
     Comparator 51 receives a mixed signal containing a pilot signal and a noise signal after having passed through capacitor C, (in which the low frequency signal IN 1  of the composite signal has been removed) via its non-inverting input port (+), and receives the pilot canceling signal via its inverting input port (-). Amplifier 52 is connected to comparator 51 so as to amplify the signal output from the comparator 51 to a predetermined level. Diode D and reference voltage source V ref  maintain predetermined levels for output signal IN 3  so as to control the transmission transistors Q 1  and Q 2 . For instance, if reference voltage source V ref  is 4.3 V, the voltage applied to the anode of diode D must exceed 5 V to turn on diode D (because the forward voltage for diode D is 0.7 V). Accordingly, when diode D is turned on, the voltage across the series configuration of diode D and reference voltage source V ref  become 5 V. 
     FIG. 4A shows the waveform of a mixed signal applied to the non-inverting input port (+) of comparator 51. FIG. 4B is the waveform of the mixed signal applied to the inverting input port (-) of comparator 51. FIG. 4C is the waveform of the output signal of comparator 51. FIG. 4D is the waveform of output signal IN 3  of the control signal generating circuit 50. 
     In FIG. 3, comparator 51 receives the mixed signal shown in FIG. 4A through its non-inverting input port (+) and receives the pilot canceling signal shown in FIG. 4B through its inverting input port (-), so as to generate a high-level output signal when noise is present and to generate a low-level output otherwise. The signal generated from comparator 51 is illustrated in FIG. 4C. Amplifier 52 connected to the output of comparator 51 amplifies the output signal of comparator 51 to a predetermined level which is thereafter kept at a predetermined level, e.g., +5 V, by the series-connected diode D and reference voltage source V ref . As a result, the output signal of the control signal generating circuit 50, i.e., the control signal IN 3 , has the same waveform as that of FIG. 4D and is used as a control signal of noise canceler 100 shown in FIG. 2. 
     When the control signal IN 3  from the control signal generating circuit 50 is &#34;LOW&#34; (when no noise signal is present), the pilot canceling signal IN 2  is switched to the inverting input port (-) of subtracter 10. This is because the control signal IN 3  is inverted by first inverter 20 of FIG. 2 so as to apply a &#34;HIGH&#34; to the gate electrode of transmission transistor Q 1  connected to the inverting input port (-) of subtracter 10. Thus, transmission transistor Q 1  is turned on and transmits the pilot canceling signal IN 2 . Subtracter 10 receives the composite signal IN 1  via its non-inverting input port (+) and receives the pilot canceling signal IN 2  having passed through transmission transistor Q 1 , via its inverting input port (-), so as to subtract the pilot canceling signal IN 2  from the composite signal IN 1 . The subtracted result is transmitted as output signal OUT via the output port. Since the composite signal IN 1  usually consists of a low frequency signal and a pilot signal and the pilot canceling signal IN 2  has the same amplitude and phase as those of the pilot signal, the output signal OUT of subtracter 10 becomes just the low frequency signal. 
     Conversely, when the control signal IN 3  from the control signal generating circuit 50 is &#34;HIGH&#34; (when a noise signal is present), the signal passing through capacitor C is applied to the inverting input port (-) of subtracter 10. The control signal IN 3  is inverted by the first inverter 20 (now &#34;LOW&#34;), is applied to and thus turns off transmission transistor Q 1  and the signal inverted by the second inverter 30 (now &#34;HIGH&#34;) is applied to transmission transistor Q 2  so as to turn it on. Thus, a derivative of the composite signal IN 1  is applied to the inverting input port (-) of the subtractor 10. Here, capacitor C blocks the low frequency signal of the composite signal IN 1  and transmits the remaining signals, that is, the pilot signal and the noise signal. The pilot signal and the noise signal are applied to the inverting input port (-) of subtracter 10. Therefore, the low frequency signal again is output from subtracter 10, so that the noise signal contained in the composite signal IN 1  is reduced. 
     FIGS. 5a and 5b are block diagrams of digital noise signal cancelers 300 according to the present invention. 
     In FIG. 5a, when a noise signal is input via microphone 310, noise signal detector 320 detects the noise signal. Address generator 330 is connected to the output of noise signal detector 320 so as to be enabled by the output signal of noise signal detector 320 and to determine a starting address of ROM 340. Then, address generator 330 sequentially counts up by ones. ROM 340 reads out inverted noise data according to the address generated by address generator 330. When the data read out from ROM 340 is applied to D/A converter 350, the D/A converter converts the data into analog form to be sent to amplifier 360. The signal from amplifier 360 is output through speaker 370. The sound from the speaker 370 cancels the noise. 
     In an alternate arrangement, the inverted noise can be added electronically as shown in FIG. 5b. When a sound plus noise is received by the microphone 310, inverted noise is regenerated from memory as described above. However, rather than using a speaker to produce actual sound waves, an adder 330 adds the signal-plus-noise (from the microphone 310) to the inverted noise. By doing this, the noise signal is canceled. 
     FIG. 6 illustrates a block diagram of a system for recording inverted noise signals stored in a memory of a digital noise signal canceler 200 according to the present invention. 
     In FIG. 6, a normalized specific noise signal is input via a microphone 210. The signal passing through microphone 210 is transmitted to an A/D converter 220 which samples and quantizes the received signal and divides the quantized signal into a predetermined number of classes so as to encode them. For instance, if the quantized signal is divided into eight classes, the number of bits required for encoding is three, and if the signal is divided into sixteen classes, four bits are required for the encoding. Thus, A/D converter 220 continues to generate data having a predetermined number of bits and sends the converted data to multiplier 230. Multiplier 230 multiplies the data output from A/D converter 220 by -1 and transmits the result to a personal computer 280. For instance, given the data of A/D converter 220 is a binary four (0100), the output data from multiplier 230 is -4. 
     One way to obtain negative data is to take the 2&#39;s complement thereof. In this method, after the complement of 1 is found for the data, the result is added to &#34;1&#34;. This can be expressed as follows: ##EQU1## 
     Under the control of CPU 250 of personal computer system 280, RAM 240 temporarily stores the output data of multiplier 230 and then stores them in an auxiliary storage 270 via an interface 260. (The media used for auxiliary storage 270 is ordinarily tape or disk.) The necessary noise patterns from the data stored in auxiliary storage 270 can be programmed in a later-mentioned ROM 340 of FIGS. 5a and 5b. 
     In other words, FIG. 6 illustrates a noise signal converter and recording system for encoding various noise signal and storing the inverted noise data thereof in a memory, using a personal computer. 
     Accordingly, the noise canceler of the present invention is useful to cancel the noises created in electrical or electronic appliances or, noises which may emanate from other appliances or from the engines of automobiles or overhead aircraft.