Abstract:
A signal sensing circuit (10) receives an electrical signal on an input (18, 20) to connect power to a controlled device in the presence of an electrical signal and disconnect power in the absense of the electrical signal. The electrical signal is capacitively coupled (28) to an amplifier (30) and low pass filter (32) for amplifying the signal and filtering out high frequency components of the signal thereby eliminating the false triggering by transient noise on the inputs. The signal is rectified (34) and compared (38) to a predetermined set point. When the signal exceeds the set point, a timer (44) is triggered. The timer (44) produces a control signal when triggered for a predetermined time, and can be retriggered by subsequent control signals which resets the predetermined time. The presence of the control signal actuates a switch (48) to supply power to the control device, such as an amplifier.

Description:
TECHNICAL FIELD 
     The subject invention relates to a signal sensing circuit for sensing the presence of a signal, and connecting and disconnecting power to a device in response thereto. 
     BACKGROUND OF THE INVENTION 
     Remote speaker systems with integral amplifiers are sometimes equipped with automatic turn-on circuits. These controls automatically energize the power amplifier upon receipt of a low level audio signal and allow the power amplifier to shut down after a given period of time after the cessation of the input signal. 
     Typical applications include automotive booster amplifiers for stereo systems, remote speakers for stereo systems, or public address installations. In some of these uses, it is simply prudent to reduce the quiescent current drain of the amplifier when no power amplification is required. In other cases, battery operation of the amplified speaker requires that power be conserved by disconnecting the main amplifier from the power source whenever no input signal is present. 
     One type of automotive automatic turn-on and turn-off system is disclosed in U.S. Pat. No. 4,453,264 issued June 5, 1984 to the inventor of the subject invention. In the automotive environment, the stereo signal comprising left and right input channels are treated identically. The input signal is AC coupled to a differential amplifier stage which generates a ground referenced signal. The signal is AC coupled to a voltage comparator. The comparator in each channel is set to develop a positive going output pulse whenever the input exceeds a predetermined level, generally 30 mV. The output pulses which follow the input signal excursions are or&#39;ed by diodes and feed an integrator capacitor. The voltage across the integrator capacitor is monitored by a MOSFET switch which in turn pulls in a power control relay. Typical transistor characteristics allow the device to turn on whenever the voltage across the integrator capacitor reaches a predetermined level, approximately 4 V. In the absence of any audio input signal, the charge on the capacitor dissipates slowly through a bleeder resistor so as to shut off the FET and drop out the relay after some delay. A problem with this system is that the turn-on sensitivity is linked directly to turn off time delay. Longer delays reduce the turn-on sensitivity because relatively large capacity required in the integrator, and the subsequent delay in reaching the 4 volt turn-on point. An additional problem with type of technology is that human hearing being essentially logarithmic in sensitivity can easily detect very low audio levels in the existing speakers if they are used. The auxiliary, amplified speakers should switch on automatically at this low level, and not at higher levels where their sudden turn-on could be very annoying. Random line noise may invariably trigger on the system. Reducing the turn-on sensitivity by increasing the comparator set point does render the system more noise immune, but increases the turn-on delay. 
     A second system is disclosed in an article titled &#34;Sound Operated Switch&#34; written by Michael Tooley and David Whitfield in Practical Electronics, May 1979 edition. The article discloses a switching circuit which turns on and off in response to an audio frequency signal. The incoming audio frequency signal is applied to an amplifier stage and then to a precision unity gain active full wave rectifier. The output excursion of the rectifier is applied to the comparator whose output is used to enable a conventional timer circuit, which is a 555 timer integrated circuit. It stresses that once the input level has risen sufficiently to trigger the circuit and enable the timer, the output of the monostable will remain high regardless of any subsequent reduction of input level. The problem with this type of design is that the system is not retriggerable. The integrated timer circuit is not retriggerable due to the fact that it receives an input signal and produces an output signal for the predetermined time after which it goes low and waits for another input signal. This would cause blanking out of the speaker. 
     SUMMARY OF THE INVENTION AND ADVANTAGES 
     The invention is a signal sensing assembly for sensing audio signal and supplying power in response thereto. The assembly comprises input means for supplying an audio signal. Filter means receives the audio signal and filters out frequency components above a first predetermined frequency to produce a filtered audio signal. Rectifier means receives and rectifies the filtered audio signal to produce a level signal. Comparator means receives the level signal and compares the level signal to a predetermined magnitude to produce a trigger signal. Timer means receives the trigger signal and producing a control signal for a predetermined time in response to said trigger signal and for resetting the predetermined time upon subsequent reception of the trigger signal. Control means receives the control signal to supply power. 
     The advantages of the subject invention include an automatic turn-on and turn-off system which uses a filter to allow only low frequency signals to trigger the system and the predetermined magnitude of the comparator to be set relatively high so that the system becomes relatively noise immune to input transients. By using a retriggerable timer, the input triggering sensitivity is separated from the timing function. Using this technique, turn off delays of any period may be realized with excellent turn-on sensitivity. Annoying clicks and pops no longer plague the system. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     Other advantages of the present invention will be readily appreciated as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings wherein: 
     FIG. 1; is a schematic diagram of the subject invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     A signal sensing assembly for sensing audio signals and supplying power in response thereto is generally shown at 10 in FIG. 1. The assembly 10 includes power supply means 12 for supplying power to the assembly 10. The power supply means 12 is a battery in the preferred embodiment. In order to conserve battery charge, the battery should only be connected to supply power when necessary. Generally, the assembly 10 senses an electrical input signal and supplies power or switches power to a device 14 in response thereto. 
     In the preferred embodiment, the assembly 10 is utilized in a vehicle having a radio receiver with wires carrying an audio signal running to amplifier 14 and speaker 16 assemblies in a location distant from the radio receiver. As generally understood, the amplifier 14 requires power supplied thereto. Therefore, the assembly 10 interconnects the battery 12 or vehicle battery 12 and the amplifier 14 to supply power to the amplifier 14 when necessary. When the assembly 10 senses an audio signal on input leads 18, 20 from the radio, and power 12 is supplied to the amplifier 14 for a predetermined time, unless retriggered. In the absence of an audio signal, no power will be supplied to the amplifier 14 therefore conserving battery 12 charge. 
     The assembly 10 includes input means 22 for receiving an electrical signal. In the preferred embodiment, the electrical signal is an audio signal received from the bridge drive of a vehicle radio. The input stage is single ended. It has been experimentally determined that sampling the differential output from the bridge drive is best done with respect to ground, even through only half the voltage excursion is available. The input means 22 includes a first single ended input 18 from the right or first channel of the radio, and a second single ended input 20 from the left or second channel of the radio. There may be one or any number of channels, and the invention is not limited to two channels. The input means 22 includes summing means 24 for receiving the first and second inputs 18, 20 and summing or adding the inputs 18, 20 to produce a combined audio signal. The summing means 24 may comprise a summing resistor R1, R2 on each channel and combined at a common point 26 to produce the audio signal. 
     The assembly 10 includes coupling means 28 for receiving the audio signal from the common point and capacitively coupling the same to eliminate dc components in the audio signal to prevent saturation of the input amplifier means 30, as subsequently discussed. The coupling means is a capacitor C1. 
     The assembly 10 further includes input amplifier means 30 and input filter means 32. The filter means 32 receives the audio signal and filters out frequencies above a first predetermined frequency, approximately 400 Hz, to produce a filtered audio signal. The amplifier means 30 amplifies the filtered audio signal. The amplifier means 30 and the filter means 32 are comprised of an operational amplifier 52 having the filter characteristics in its feedback. The use of the ac coupling 28 in conjunction with the high frequency attenuation afforded by the filter 32 and amplifier 30, yields a bandpass characteristic. Restricting the frequency band to essentially a 50 Hz to 400 Hz range, effectively keeps noise from triggering the timer 44, as subsequently described. 
     The output from the input amplifier means 30 is capacitively coupled by a capacitor C2 to rectifier means 34. The rectifier means 34 receives and rectifies the amplified audio signal to produce a level signal. The rectifier means 34 is generally a half wave rectifier, comprising a diode D1. The rectifier means 34 is connected to a low pass filter 36. The low pass filter 36 receives the output from the rectifier means 34 and allows frequency signals below a second predetermined frequency to produce the level signal. With the values herein indicated, maximum voltage gain is realized at about 200 Hz. For a 50 mV peak to peak input at 200 Hz, a recovered d.c. voltage of about 0.5 V is generated as the level signal. Input levels of this order are barely audible in an 8 ohm speaker and charge the filter capacitor in under 0.5 seconds. 
     The assembly 10 includes comparator means 38 which receives the level signal and compares the level signal to a predetermined magnitude to produce a trigger signal. The comparator means 38 is generally an operational amplifier 40 configured as a comparator wherein the non-inverting input receives the trigger signal and the inverting input is connected to the predetermined magnitude or set point 42. The predetermined magnitude is set at a relatively high level, approximately 0.3 volts allowing the assembly 10 to become reasonably noise immune to input transients associated with noise. The comparator 38 acts as a digital level shifter developing a positive output whenever the level signal exceeds nominally 0.3 volts. 
     The assembly 10 includes timer means 44 for receiving the trigger signal to produce a control signal for a predetermined time and for resetting the predetermined time delay upon each subsequent reception of the trigger signal. At the expiration of the predetermined time a second signal is produced indicative of turning off the switch 48. The control signal is initiated and produced within a specified time from the reception of the trigger signal, wherein the predetermined time is independent of the specified time. The specified time may comprise the turn-on time of the device 14, which is substantially instantaneous. Whereas the predetermined time may be varied by using different valued components, and which is not dependent on the turn-on time as in the prior art. A positive trigger signal initiates the predetermined time delay. The timer means 44 includes retriggerable monostable 46, such as standard CMOS digital component CD4047B, for producing the control signal for the predetermined time and for resetting the predetermined time in response to a subsequent reception of the trigger signal. The control signal may be chosen to be either high or low. 
     The control means 48 receives the control signal to supply power to a device 14. The control means 48 is generally a solid state switch or relay responsive to the monostable timer 44 and which connects power. The switch 48 is generally a relay which is energized by the retriggerable monostable 44 and connected to power 12. The switch 48 closes to connect power to the amplifier 14 when the control signal is produced and opens to disconnect power to the amplifier 14 in the absence of the control signal. 
     In the preferred embodiment, the switch 48 will connect power to the amplifier 14. The amplifier 14 also receives the inputs 18, 20 for amplifying same when power is supplied to the amplifier 14. 
     The more specific circuitry includes a resistor R1, R2 (both 10K.) connected to each input 18, 20 and to the common point 26. The capacitor C1 (1uF) is connected to the common point 26 and the inverting input of operational amplifier 52, the input amplifier 30 and filter 32. A resistor R3 (100K.) and capacitor C3 (0.01F.) are connected in parallel between the inverting input and output of the op-amp 52. The non-inverting input is connected to a resistor R4 (100K.) to power and to a resistor R5 (100K.) to ground and to a capacitor C4 (1uF) to ground. The output of op-amp 52 is connected to capacitor C2 (1uF) to the rectifier 34. The capacitor D2 is connected to diode D1 and to resistor R6 (10K.) to ground. The output of the diode D1 is connected to resistor R12 (10K.). Resistor R12 is connected to capacitor C6 to ground and to resistor R7 (100K.) to ground, comprising the low pass filter 36. The resistor R12 is connected to the non-inverting input of operational amplifier 40 of the comparator 38. The set point is connected at the inverting input and comprises a resistor R8 (2.4K.) connected to ground and the inverting input, resistor R9 (100K.) connected to power and the inverting input, and a capacitor C7 (1uF) connected to power and ground. The output of the comparator 38 is connected to pin 12 of the monostable 46. Pins 4 and 14 are connected to power, pins 8 and 12 are connected to resistor R10 (100K.) to ground, pins 5, 6, 7, and 9 are grounded, pin 1 is connected through capacitor C8 (0.47uF) to pin 3 and to pin 2 through resistor R11 (10M.), and pin 10 produces the control signal. 
     Also included is a method of sensing audio signals and supplying power to a device in response thereto. The method includes the steps of receiving an audio signal, filtering out frequency components above a first predetermined frequency in the audio signal to produce a filtered audio signal, rectifying the filtered audio signal to produce a level signal, comparing the level signal to a predetermined magnitude to produce a trigger signal, producing a control signal for a predetermined time in response to the trigger signal and for resetting the predetermined time upon subsequent reception of the trigger signal, receiving the control signal to supply power to a device. Also included are the steps of receiving the output from the rectifying step and allowing frequency signals below a second predetermined frequency to produce the level signal, receiving a first single ended input from a first channel and second single ended input from a second channel to produce the audio signal, and summing said inputs to produce a combined audio signal for the filtering. 
     It is to be understood that the subject invention may be used in any environment where a switch is controlled by the presence or absence of an electrical signal. 
     The invention has been described in an illustrative manner, and it is to be understood that the terminology which has been used is intended to be in the nature of words of description rather than of limitation. 
     Obviously, many modifications and variations of the present invention are possible in light of the above teachings. It is, therefore, to be understood that within the scope of the appended claims wherein reference numerals are merely for convenience and are not to be in any way limiting, the invention may be practiced otherwise than as specifically described.