An improved variable gain circuit is described having an input for an audio signal and an output for an audio signal. An operational amplifier having inverting and non-inverting inputs and an output has its input connected to the audio input. The first differential cell having inverting and non-inverting inputs, output, and a first control current terminal, has one input connected to the output of the operational amplifier and the other input connected to a reference potential. The output of the first differential cell is connected to one of the inputs of the operational amplifier in negative feedback relation and a source of controlling current is connected to the control current terminal. The second differential cell is also provided having inverting and non-inverting inputs, an output, and a second control current terminal. one input of the second differential cell is connected to the output of the operational amplifier and the other of the inputs is connected to the source of reference potential. The second control current terminal is connected to a second source of controlling current and the output of the second differential cell provides a current having a gain which is substantially the ratio of the second to the first controlling current.
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12. An improved variable gain circuit comprising:
input means for inputting an audio signal; reference potential means for generating a reference voltage; operational amplifier having inverting and non-inverting inputs and an output wherein th inverting input of said operational amplifier is coupled to aid input means and said non-inverting input is coupled to said reference potential means; input differential cell having inverting and non-inverting inputs and an output wherein the non-inverting input of said differential cell is coupled to the output of said operational amplifier, the inverting input of said input differential cell means is coupled to said reference potential means and the output of said input differential cell means is coupled to the inverting input of said operational amplifier; and output differential cell having first and second inputs and an output wherein one input to said output differential cell means is coupled to the non-inverting input of said operational amplifier and the other input to said output differential cell means is coupled to said reference potential means wherein the ratio of currents flowing in input and output differential cell means controls the gain of said variable gain circuit.
7. An improved variable gain circuit comprising:
input means for inputting an audio signal; reference potential means for generating a reference voltage; operational amplifier having inverting and non-inverting inputs and an output wherein the inverting input of said operational amplifier is coupled to said input means and said inverting input is coupled to said reference potential means; input differential cell having inverting and non-inverting inputs, a current control terminal and an output wherein the non-inverting input of said input differential cell is coupled to the output of said operational amplifier, the inverting input of said input differential cell is coupled to said reference potential means and the output of said input differential cell means is coupled to the inverting input of said operational amplifier; and output differential cell having first and second inputs, a current control terminal and an output constituting the output of said variable gain circuit, wherein said first input of said output differential cell means is coupled to the output of said operational amplifier and said second input to said output differential cell is coupled to said reference potential means wherein the ratio of currents flowing in said first and second control current terminals of said input and output differential cells controls the gain of said variable gain circuit.
1. An improved variable gain circuit comprising:
input means for inputting an audio input signal; output means for outputting an audio output signal; an operational amplifier having inverting and non-inverting inputs and an output wherein one of said inputs is connected to said input means; a source of reference potential; first and second sources of controlling currents; a first differential cell having inverting and noninverting inputs, an output and a first control current terminal, wherein one input of said first differential cell is connected to said output of said operational amplifier, and the other of said inputs is connected to said source of reference potential, and said output of said first differential cell is connected to one of said inputs of said operational amplifier in negative feedback relation, and further wherein said first control current terminal is connected to said first source of controlling current; and a second differential cell having inverting and noninverting inputs, an output and a second control current terminal, wherein none input of said second differential cell is connected to said output of said operational amplifier and the other of said inputs is connected to said source of reference potential, said output of said second differential cell connected to said output means, and said second control current terminal connected to said second source of controlling current, wherein the current gain of said variable gain circuit is substantially the ratio of said second to said first controlling current.
2. An improved variable gain circuit comprising:
input means for inputting an audio signal; reference potential means for generating a reference voltage; operational amplifier having inverting and noninverting inputs and an output wherein the inverting input of said operational amplifier is coupled to said input means and said non-inverting input is coupled to said reference potential means; input differential cell means having inverting and non-inverting inputs, a current control terminal and an output for providing an output current which is proportional to current flowing in said inverting and non-inverting inputs wherein the non-inverting input of said differential cell is coupled to the output of said operational amplifier, the inverting input of said input differential cell means is coupled to said reference potential means and the output of said input differential cell means is coupled to the inverting input of said operational amplifier; and output differential cell means having first and second inputs, a current control terminal and an output for providing an output current which is proportional to current flowing in said first and second inputs wherein said first input of said output differential cell means is coupled to the non-inverting input of said input differential cell and said second input of said output differential cell means is coupled to said reference potential means wherein the ratio of currents flowing in said current control terminals of said input and output differential cell means controls the gain of said variable gain circuit.
13. An improved variable gain circuit comprising:
input means for inputting an audio signal; reference potential means for generating a reference voltage; operational amplifier having inverting and noninverting inputs and an output wherein the inverting input of said operational amplifier is coupled to said input means and said non-inverting input is coupled to said reference potential means; input differential cell means coupled to said input means and said operational amplifier means, said input differential cell having first and second input devices and a current control terminal wherein said first input device is coupled to the inverting input of said operational amplifier means and for generating an operational amplifier output signal which is nonlinearly related to said input audio signal wherein said first input device is coupled to said reference potential means and further wherein said operational amplifier output signal is developed across said second input device; and output differential cell means having first and second inputs, a current control terminal and an output for providing an output current which is proportional to current flowing in said current control terminal and which is non-linearly related to the voltage on said first and second inputs wherein said first input of said output differential cell means is coupled to said operational amplifier output signal and said second input of said output differential cell means is coupled to said reference potential means wherein the ratio of currents flowing in said current control terminals of said input and output differential cell means controls the gain of said variable gain circuit.
3. The apparatus of claim wherein said improved variable circuit may be operated at voltages as low as 0.95 volts.
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This invention relates to the field of audio signal processing and specifically to an improved variable gain circuit suitable for use with audio compressors.
Audio compressors are well known devices which are used to modify the dynamic range of an audio signal. An audio compressor may be considered as having two parts: an electronically controlled variolosser or gain adjusting device and a control system with associated circuits to generate control signals which control the gain of the device as a prescribed function of the input (or output) signal. Variolossers are also useful in other applications. For example, a variolosser may be used as a fixed gain device such as a preamplifier or filter with slight modifications.
Audio compressors are characterized in two categories. If the control signals are derived from the input signal of the compressor, the compressor is sad to be of the feedforward type; if the control signals are derived from the output of the compressor, the compressor is said to be of the feedback type. The feedforward configuration requires that the dynamic range of the gain control circuitry be equal to that of the input signal. The advantage of this configuration is that the circuit is inherently stable. In a feedback configuration, a larger range of signals can be accurately processed since the gain control signal samples the output signal which has already been compressed. However, instability is often a problem with feedback compressors. In either of the above cases, a derived control voltage is used to control the loss or gain of the variable loss circuit.
Because of the trend toward miniaturization in electronics today, many audio devices are being designed to operate with single cell batteries. In the field of audio signal processing, a need exists to manufacture compressors, expanders, amplifiers, and filters which may be operated at very low voltages. Low voltage applications for these devices are numerous. However, because of the complexity of the functions provided by compressors and expanders it has previously been impossible to manufacture these circuits in a topology which functions reliably at power supply voltages as low as 1 volt and provide a continuously variable compression ratio. For an example of a low voltage compressor circuit employing the variolosser of the present invention, refer to U.S. patent application No. 159,949 invented by the present inventors and filed of even date herewith.
Operation at low voltage allows a compressor or expander to be powered by a single cell battery. However, operation from a single cell battery severely limits the amount of total power available to the circuitry powered therefrom. Therefore, it is also desirable to design low voltage circuitry wherein the current consumption of the circuitry is minimized.
Briefly described, the present invention contemplates the use of a variable gain circuit which includes an input means for inputting an audio signal. An operational amplifier having inverting and non-inverting inputs and an output is disposed with one of its inputs coupled to the input means. A first differential cell having inverting and non-inverting inputs, an output and a first control current terminal is disposed with one input of the first differential cell connected to the output of the operational amplifier and the other input coupled to a source of reference potential. The output of the first differential cell is coupled to the inverting input of the operational amplifier in negative feedback relation.
A second differential cell having inverting and non-inverting inputs, an output and a second control current terminal is disposed with one input of the second differential cell connected to the output of the operational amplifier and the other of the inputs coupled to the source of reference potential. The output of the second differential cell comprises the output of the improved variable gain circuit. The first and second control current terminals of the first and second differential cells, respectively, are coupled to first and second sources of controlling currents wherein the current gain of the variable gain circuit is substantially controlled by the ratio of the second to the first controlling current.
Accordingly, it is an object of the present invention to provide a variable gain circuit which is operable from a low voltage battery.
It is another object of the present invention to provide a variable gain circuit wherein current consumption is minimized.
It is another object of the present invention to provide a variable gain circuit which may be used to expand or compress an audio signal.
It is yet another object of the present invention to provide a continuously variable gain circuit which is easily manufactured in the form of an integrated circuit.
It is still another object of the present invention to provide a continuously variable gain circuit wherein the maximum signal handling capability is provided for the largest input signals.
These and other objects may be fully appreciated through the description below and the accompanying drawing in which:
FIG. 1 is a schematic diagram of a prior art compressor adapted for use with a telephone system.
FIG. 2 is a schematic diagram of the variable gain circuit of the present invention.
FIG. 3 a detailed schematic diagram of the circuit of FIG. 2 disposed in a controllable gain configuration.
A variable gain circuit is one component of a compressor or expander wherein the gain of the circuit is varied under the control of a control circuit based on a desired relationship between the input and output signals. In the case of the present invention, the variable gain circuit or variolosser is a current multiplier whose transfer function is linear. One example of a prior art variolosser is shown in FIG. 1. This device is a Signetics NE572 and it is of the feedback type. In the circuit 100, the input signal is coupled to a differential amplifier 102 through a resistor 104. The differential amplifier 102 is comprised of transistors 106 and 108 which are coupled in a common emitter configuration. The base and collector of transistor 106 are coupled together. The base/collector connection of transistor 106 is further coupled to the input of operational amplifier 110.
The output stage of circuit 100 is comprised of differential pair 112 which is formed by transistors 114 and 116. The base terminal of transistors 108 and transistor 114 is coupled in common. This common connection is further coupled to the output of operational amplifier 110. Current sources 118 and 120 are coupled between the common emitters of differential pairs 102 and 112 and a reference terminal 122. Current sources 124 and 126 are coupled to the collectors of transistors 114 and 116, respectively. Current source 124 is a variable current source whose output current depends on the output of current source 126. A current source 128 is coupled to the collector/base connection of transistor 106.
In this type of variable gain circuit, a compressor is formed by placing the variolosser in the feedback loop of an operational amplifier and accordingly is prone to instability. Current gain in this device is controlled by varying the output current Ig in differential pair 112 relative to the fixed current I2 in differential pair 102. The circuit relies on the virtual ground between the input of operational amplifier 110 (with negative feedback) to maintain equal base-to-emitter voltages between its two emitter coupled pairs 102 and 112 and the input diode formed by transistor 106. As an increasing signal appears at the input terminal 130, the current therefrom is summed with the current generated by current source 1128 at the input of operational amplifier 110 which generates a decreasing output voltage in response thereto. This decreasing voltage lowers the base voltage of transistor 114. This in turn causes current sources 124 and 126 to generate a relatively lower current at output terminal 132. In a similar fashion, a decreasing input current at terminal 130 will cause current sources 124 and 126 to generate a relatively higher current at output terminal 132. Therefore, the current consumption of circuit 100 varies as a function of input current.
In order to vary the current gain of circuit 100 from 0 dB to 20 dB, a 20 dB change in the gain control signal (Ig) is required. As a result, the power dissipation of the circuit 100 increases as a function of the gain control signal Ig. In addition, this circuit requires a relatively high voltage (e.g., 5 volts) for proper operation.
The present invention provides an improvement over the circuit 100 by varying the current in the input and output differential cells independently or in opposite directions. A 20 dB increase in current gain is achieved by redistributing the quiescent current between the input and output differential pairs such that the current through the output cell is 20 dB greater than the current through the input cell. As a result, the power dissipation may be independent of the gain set by the cell current control signals.
Referring now to FIG. 2, the present invention includes differential cells 203 and 205 comprising differential pairs 202 and 204. Differential pair 202 is formed by transistors 206 and 208 and differential pair 204 is formed by transistors 210 and 212, respectively. Each of the differential pairs 202 and 204 are further coupled to current mirror loads 214 and 216, respectively. Current mirror 214 is formed by transistors 218 and 220 which are coupled with their bases in common. Current mirror 216 is formed by transistors 222 and 224 which are coupled with their bases in common. Transistors 220 and 224 are each disposed with their bases and collectors in common and accordingly they function as diodes and are hereinafter referred to as current mirror reference transistors. The current flow out of the collectors of transistors 220 and 224 establishes a base/emitter voltage in the current mirrors which causes a mirrored current to be generated at the collectors of transistors 218 and 222 which is controlled by the relative sizes of the devices. In other words, if for example, transistors 220 and 218 are of identical size, whatever current is generated by transistor 220 will be substantially generated by transistor 218 in a 1--1 relationship.
In the present invention, the differential cells 203 and 205 are coupled in a pairwise configuration. Specifically, the bases of transistors 208 and 210 are coupled together and the bases of transistors 206 and 212 are coupled together. Stated alternatively, the inverting input of differential cell 203 is coupled to the non-inverting input of differential cell 205 and vice versa. Operational amplifier 226 is disposed with its inverting input coupled to the common collector connection of transistors 206 and 218 and its non-inverting input coupled to the common base connection of transistors 206 and 212. The common base connection of transistors 206 and 212 is further coupled to a source of reference potential 230. The output of operational amplifier 226 is coupled to the common base connection of transistors 208 and 210. In another aspect of this invention, the base inputs of output differential cell transistors can be interchanged to provide a phase reversal from input to output.
One interesting aspect of the present invention lies in the fact that the input current at input terminal 228 is applied to the collectors of transistors 206 and 218 in parallel. Positive input currents therefore add directly to the collector current of transistor 206 (and vice versa). By virtue of the pairwise connections of the differential cells 203 and 205, equal base/emitter voltages are generated in transistors 206, 212 and 208, 210. As a result, the ratio of the collector currents in the differential pair 204 is equal to the ratio of the collector currents in differential pair 202.
Negative feedback is generated by operational amplifier 226 and is established through transistors 206 and 208 which provide a low impedance summing node for the input current as well as the properbase bias current for transistors 208 and 210. Under quiescent conditions, (Iin=0) the differential pairs 202 and 204 are balanced with IC1=IC2 and IC4=IC5 (neglecting the small base currents). As the input current increases, increased current IC1 is injected into the collector of transistor 206 and therefore the base/emitter voltage of transistor 206 increases while IC2 and the base/emitter voltage of transistor 208 decreases. Similarly, IC5 and the base/emitter voltage of transistor 210 decreases while IC4 and the base/emitter voltage of transistor 212 increases, thus producing an output current.
In yet another aspect of the present invention, the input signal may be applied to the collectors of transistors 208 and 220. In this case, in order to maintain the negative feedback relation, operational amplifier 226 is disposed with its non-inverting input coupled to the common collector connection of transistors 208 and 220 and its inverting input coupled to the common base connection of transistors 206 and 212.
The ratio of the output current to the input current, the current gain, is determined by the ratio of the total amount of current steered out of the common emitter connections of the differential cells 202 and 204. In other words, the current gain of the variolosser 200 is determined by the ratio of the quiescent collector currents Ia and Ib of transistors 232 and 234 which are coupled to the respective common emitter connections of differential pairs 202 and 204.
The quiescent collector currents of transistors 232 and 234 are controlled by their respective base voltages. Assuming the transistor at the input and output cells are the same size, if Ia is equal to Ib, the gain of circuit 200 is unity. If Ia is smaller than Ib, the gain is greater than unity and vice versa. The respective base voltages of transistors 232 and 234 may be controlled voltage sources 236 and 238. In some applications, voltage source 238 may produce a fixed reference voltage. Voltage source 236 may be a variable voltage source which produces a control voltage (Vcont). Therefore, the relative base voltages of transistors 232 and 234 and the respective currents Ia and Ib may be controlled by Vcont. This control voltage may be derived from a rectifier/filter combination (not shown) coupled to the input signal of circuit 200. It can be positive or negative simply by the choice of rectifier output polarity, thus providing both compression and expansion functions. If Vcont is positive, the circuit 200 functions as a compressor. If Vcont is negative, circuit 200 functions as an expander. Thus, the circuit 200 provides both compression and expansion by merely changing the rectifier polarity. Of course, the variolosser 200 may be operated as a fixed gain device by maintaining Vcont at a constant level.
The variolosser 200 provides a large range of current gain which may be in the range of 80 dB under the control of a small linear dc voltage which may be in the range of -120 mV to +120 mV. The sensitivity of circuit 200 may therefore be in the range of 0.334 dB/mV. This is achieved by using the control voltage to control the base/emitter voltages of current sink transistors 232 and 234, thereby taking advantage of the exponential relationship between the collector current and the base-emitter voltage of a transistor in the active region.
In the circuit 100, the variolosser relies on the virtual ground between the inputs of operational amplifier 110 (with negative feedback) to maintain equal base/emitter voltages between its two differential amplifiers and has its input applied to a diode. In contrast, the present invention maintains equal base/emitter voltages by direct connection and utilizes feedback around operational amplifier 226 to establish appropriate base current bias. Since the input signal of the circuit 200 is applied to a current mirror that is identical to the output current mirror, by virtue of the pairwise connection of differential cells 203 and 205, current consumption may be held constant regardless of the input signal level.
In another aspect of the present invention, gain reduction occurs as the magnitude of the input signal increases. As mentioned above, the circuit 200 achieves gain reduction by steering more current into its input stage than its output stage. As a result of this action, and the action of the input current mirror, the variolosser exhibits maximum signal handling ability for the largest input signals (minimum gain), since the input signal enters the cell at the point where the largest current is available. The present invention provides a variolosser structure which may be operated successfully at very voltages even with the small transistors used in small integrated circuits. As a result of its low voltage operation, this circuit is well suited for hearing aids and other low voltage applications.
Referring now to FIG. 3, there is shown a more detailed schematic of the circuit of FIG. 2 which features improved low voltage performance. In the embodiment shown in FIG. 3, the variolosser is implemented as an adjustable gain circuit. For the sake of clarity, components which provide identical functions as the components of FIG. 2 bear identical designations. As above, the circuit 300 includes differential amplifiers 202 and 204 which are coupled to current mirror loads 214 and 216, respectively. The pairwise connection of the differential cells 203 and 205 is identical to the connections described in conjunction with FIG. 2. The operational amplifier 226 is disposed with its inverting input coupled to the common collector connection of transistors 218 and 206 and its non-inverting input is coupled to the common base connection of transistors 206 and 212 and to the source of reference potential 230.
The operational amplifier 226 is formed by a differential pair 302 comprising transistors 306 and 308. These transistors are coupled to a current mirror load 314 formed by transistors 318 and 320 which are disposed with their bases coupled together. The base and collector of transistor 320 are coupled together, thereby forming the diode portion or reference transistor of the current mirror 314. A PNP transistor 322 forms the output stage of operational amplifier 226. The base of PNP transistor 322 is coupled to the common collector connection of transistors 306 and 318. The emitter of PNP transistor 322 is coupled to the power supply input terminal 225 and its collector is coupled to the common base connection of transistors 208 and 210. The configuration of the operational amplifier 226 is well known and its operation will be understood by a person of ordinary skill in the art. Its function in the circuit 300 is identical to the functional operation of operational amplifier 226 described in conjunction with FIG. 2.
Reference currents for operational amplifier are provided by the reference current generator 340, which includes NPN transistors 342 and 344 coupled in a current mirror configuration. Each of these transistors are coupled with their emitters coupled to ground terminal 235. The collector of transistor 344 is coupled to the emitter connection of transistors 306 and 308, thereby forming the current sink for differential pair 302. The current sinking capability of reference current generator is controlled by transistor 342, disposed with its collector and base coupled together, and resistor 334. Since transistor 342 is clamped to ground, a fixed voltage drop will be developed across resistor 334 causing a fixed current to flow through resistor 334 into transistor 342 which will be mirrored in transistor 344, thus establishing the current consumption of operational amplifier 226.
As above, the gain of the circuit 300 is set by the ratio of currents Ia and Ib flowing into the collectors of transistors 232 and 234, respectively. These currents may be controlled in a number of ways. In one embodiment, the bases of transistors 232 and 234 could be coupled to the common base connections of the reference current generator 340 and the relative currents flowing in transistors 232 and 234 could be set by controlling the relative areas of the respective devices. In the embodiment shown, transistors 232 and 234 are coupled in current mirror configurations with the addition of transistors 350 and 354, respectively. Transistors 350 and 354 are disposed with their emitters coupled to ground terminal 235 and their collectors and bases coupled in common wherein this common connection is further coupled to the bases of transistors 232 and 234, respectively. Variable resistors 352 and 356 may be coupled between the power supply input terminal 336 and the respective common base/collector connections of transistors 350 and 354 so that the ratio of the settings of variable resistors 352 and 356 controls the gain of circuit 300. As mentioned above, the bias voltage for transistors 232 and 234 may also be generated by a control voltage generator to provide compression and expansion functions.
The low voltage operation aspect of this invention can be appreciated by reference to FIG. 3. The circuit 300 is operable from voltages as low as or lower than 1.1 volts. As a result of this low voltage operation, it is well suited for applications such as hearing aids or portable radios. The minimum operating supply voltage for the circuit 300 is determined by the total number of series voltage drops necessary to keep all of the transistors of the circuit in their proper region of operation. FIG. 3 shows that the circuit 300 has three critical series voltage drops: the base/emitter voltage of transistor 220, the collector/emitter voltage of transistor 208 and the collector/emitter of voltage of transistor 232. At low bias currents, transistors with appropriately small dimensions for integrated circuits useful in in-the-ear hearing aids will have a base/emitter voltage in the range of 0.65 volts and a collector/emitter voltage in the range of 0.15 volts. Therefore, even with these small dimensions, the circuit 300 can be operated from voltages as low as 0.95 volts.
In summary, a low voltage variable gain circuit has been described. The present invention includes a two stage differential amplifier structure coupled in a pairwise configuration. The feedback and bias level of the circuit is controlled by an operational amplifier coupled to the input differential amplifier. As the gain of the variolosser is varied, current is diverted between the input and output stages so that the total current consumed by the circuit may be held constant regardless of the gain of the device. The unique topology of the present invention allows reliable circuit operation from a low voltage power source. Accordingly, other uses and modifications will be obvious to a person of ordinary skill in the art and all of such modifications are intended to be within the scope of the present invention.
Waldhauer, Fred D., Baez, Carlos A.
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Feb 23 1988 | ReSound Corporation | (assignment on the face of the patent) | / |
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