FIELD OF THE INVENTION

The subject invention relates to high gain amplifying stages by output conductance cancellation techniques, and in particular, to amplifier stages utilising MOS (Metal-Oxide-Semiconductor) technology.

BACKGROUND OF THE INVENTION

In prior art MOS technology, the gain is severely limited by the inherently low transconductance, g_m, of the MOS transistor. The transconductance in a MOST (MOS transistor) is proportional to the ratio Z/L (the channel width (Z) to the channel length (L) of the device). Any attempt at increasing the gain by increasing the channel width (Z) of the device, or by cascading gain stages, results in large area consumption and increase in parasitic capacitances. Decreasing the channel length (L) of the MOS transistor to increase the transconductance has its limitations in the fact that it causes a degradation (increase) in output conductance g_o of the device and thus causes a degradation of the voltage gain which is proportional to the ratio g_m /g_o. Therefore, attempts to overcome the low transconductance by modifying the Z/L ratio are not suitable.

A MOS transistor, as shown in FIG. 1a, may be represented by a small signal model which consists of a current generator g_m v_i, (where v_i is the input gate voltage) and an output conductance g_o. (FIG. 1b).

An inverting gain stage comprising a driver transistor 10 and a load transistor 12 is shown in its most general form in FIG. 2. The driver transistor current generator (g_md v_i) is a function of the input signal v_i only, while the current generator [g_m1 (k_a v_i +k_b v_o)] in the load transistor can be affected by both the input and/or the output signals. The small signal gain of the generalized inverter of FIG. 2 is given by ##EQU1## where g_load is the effective conductance of the load transistor and is given by g_load =g_o1 +k_b g_m1 The constants k_a and k_b can have a value of one or zero depending on the type of inverter. Examples of which are shown in FIGS. 3(a), (b) and (c).

The principal disadvantage of the above-mentioned gain stage is that the maximum gain obtainable is low due to the low value of g_m and the high value of g_o, particularly in the case of short channel MOS transistors. The maximum gain is given by ##EQU2## and is achieved using the CMOS stage shown in FIG. 3a.

An object of the present invention is to provide a higher gain amplifying stage than is achievable with the prior art.

A higher gain stage is accordingly provided which utilizes a negative conductance to reduce the total load conductance of the amplifying stage. The new arrangement allows positive feedback to be delivered to the input of the load, which causes K_b 0 and effectively reduces g_load. g_load can be reduced from positive to negative values by decreasing the attenuation of a positive feedback stage A. A negative g_load can then be used to cancel the positive output conductance of the driver g_od, as well as the resistance of the load R_L. This can result in a near infinite voltage gain. In addition, the presence of positive feedback introduces phase lead which may have useful implications in amplifier design.

The high gain amplifier of the subject application is particularly adaptable to implementation in amplifiers, comparators and oscillators. An important advantage of this invention is that the high gain is provided by a single stage only; this allows easier composition of the amplifier and also frees the input and the output stages from the requirements of providing gain. Those stages can then be designed to optimise other input/output specifications such as input offset, dynamic range and current driving capability.

BRIEF DESCRIPTION OF THE DRAWINGS

The preferred embodiment and best mode contemplated for implementing the subject invention will now be described in detail with reference to the accompanying drawings of which:

FIGS. 1a and 1b are models for a single MOS transistor according to the prior art;

FIG. 2 is the equivalent circuit of an inverting stage using the small signal model of FIG. 1b;

FIGS. 3a, 3b and 3c are three examples of MOS inverters according to the prior art with the type of inverter being selected by the value of the constants k_a and k_b ;

FIG. 4a demonstrates the basic configuration of the improved high gain amplifying stage in small signal equivalent circuit form according to the present invention;

FIG. 4b demonstrates a CMOS implementation of the amplifying stage of FIG. 4a;

FIG. 5a shows a practical circuit configuration of the amplifying stage according to the present invention realised in a CMOS implementation;

FIG. 5b is a graph demonstrating the adjustable (from positive to negative slopes) load lines of the amplifier shown in FIG. 5a;

FIG. 5c shows the corresponding programmable transfer curves obtained by varying the amount of positive feedback with R_L =1kΩ;

FIG. 6a is a block diagram representing an operational amplifier or comparator using a gain stage realised in accordance with the present invention;

FIG. 6b shows a practical realization of the operational amplifier of FIG. 6a implemented in CMOS technology.

FIG. 6c shows transfer curves obtained with the operational amplifier of FIG. 6 with varying amounts of positive feedback applied to the high gain stage.

FIG. 7a shows the transfer curves obtained when the gain is adjusted to be larger than that required for total conductance cancellation;

FIG. 7b is a circuit diagram of a voltage control oscillator using the principles according to the present invention with the gain adjusted to be larger than that required for total conductance cancellation.

FIG. 7c is a graph of output pulses resulting from the circuit of FIG. 7b when the voltages V_a and V_b are controlled.

DESCRIPTION OF PREFERRED EMBODIMENT

Referring now to FIG. 4a of the drawings, the principle of the invention is demonstrated. The load transistor 20 of the gain stage has been provided by means of positive feedback, with a v_o dependent current generator 22 having an effective negative transconductance value -g_m1 A, where the attenuation A is less than 1, and is provided by the stage 24 (see FIG. 4b). The input signal v_i is delivered to the free input of the driver transistor 21. The effective output conductance of the load transistor 20 in this case can be shown to be

gload =go1 -gm1 A.

where g_o1 is the actual output conductance of the load transistor 20, and g_m1 is the actual transconductance of the load transistor 20.

A constant attenuator, is not desirable, since g_load would become a direct function of g_m1, whose value depends on the instantaneous value of -Av_o. Since g_load varies with the level of v_o, exact conductance cancellation with g_od can only be attained at a limited output range about the quiescent point.

Referring now to FIG. 5a, the above principle is demonstrated by a novel gain stage which is realized using standard CMOS technology. An optimal A stage 26 was designed to offer improved output swing and maintain high gain over a wider range of output voltages. The attenuation of M2, M3 and M4 (which form the attenuator 26) is not constant and is approximately given by ##EQU3## where g_o2 and g_m4 are the output conductance and transconductance of transistors M₂ and M₄ respectively. Since g_m4 tracks g_m1, the dependence of g_load on g_m1 can be cancelled. The resulting g_load is nearly independent of the operating point and is given by

gload =g01 -g02 -1/R.sbsb.2

Therefore, g_o cancellation can be maintained over a wide range of output voltages.

The final voltage gain is given by ##EQU4## where maximum gain is achieved by selecting ##EQU5##

The Zener diode Z₁ and limiting resistor R₁ are required to prevent hard current cutoff in transistor M₄ and transistor M₂, resulting in the characteristic shown by line 28 in FIG. 5b. This occurs when v_o falls below [V_B -V_T2)+V_T3 ], where V_B is the bias voltage and V_T2 and V_T3 are the threshold voltages of transistors M₂ and M₃ respectively (in other words, without Z₁, if the gate to source voltage of transistor M₃ is less than the threshold voltage V_T3 of M₃, the whole stage is driven into hard cut-off).

The adjustable load lines generated by this scheme are shown in FIG. 5(b), the instantaneous slope gives the value for g_load. FIG. 5(c) shows the corresponding programmable transfer curves obtained by varying the attenuation provided by A with R_L =1KΩ. As the values of A decreased, the transfer curves exhibited higher voltage gain, as well as increased voltage swing.

The embodiment described may be used as an operational amplifier by simply adding an input stage 30 and an output stage 32 as shown in FIG. 6a. The main advantage of this configuration is that the high gain is provided by a single stage.

As an implementation of FIG. 6a, an experimental operational amplifier, designed using short channel MOST's, was fabricated and shown in FIG. 6b. Excellent DC transfer characteristics was observed and illustrated in FIG. 6c. In FIG. 6c when no positive feedback is used, the amplifier has a voltage gain of less than -250 (curve a). The voltage gain is the slope Vo/Vi of the curve in FIG. 6c. As R₂ is decreased, improvements in both voltage gain and output swing are observed. Maximum gain was observed at R₂ ≅23kΩ (curve b). In the range-3V≦v_o ≦0, the effective voltage gain is better than 10,000. The gain stage therefore improved the gain of the operational amplifier by more than 40 times. Higher gain would still be possible with the optimum choice of (Z/L) aspect ratios for the transistor, since this can increase the infinite gain range of the transfer curve. When R₂ is reduced further, a hysterisis effect is observed (curve c).

When "A" is adjusted to be larger than required for total conductance cancellation, the transfer curves obtained exhibit a hysterisis effect as shown in FIG. 7a. Such a characteristic is ideal for the implementation of oscillators. A CMOS voltage controlled oscillator circuit is shown in FIG. 7b. The gain stage differs slightly from the previous case. The Zener diode Z₁, and resistors R₁, R₂, have been eliminated. The voltage V_B applied to the gate of M₂ can be used to control the separation between the triggering points and control the frequency of oscillation. By adding transistor M₅, the voltage V_A can be used to adjust the offset of the trigger which in turn governs the duty cycle of the output pulse. The resulting output pulses shown in FIG. 7c illustrate the different frequencies and duty cycles which can be obtained by controlling V_A and V_B.

It will be readily apparent that various changes may be made to the description of the embodiments and related drawings without affecting the scope of the invention. For example, the principle of the invention could readily be implemented in single channel Metal-Oxide Semiconductor (NMOS or PMOS) technology. The same can be said for implementations using an inverted CMOS configuration, where the roles between the n-channel and p-channel transistors are reversed. In addition, it will be readily appreciated substrates of the MOS devices, may be connected to sources or to the power supplies without significantly affecting the principle of the invention.