RU2319294C1 - Cascade differential amplifier - Google Patents

Abstract

FIELD: radio engineering and communications, possible use as device for amplifying analog signals, in structure of analog microchips of various functional purpose (for example, in operational amplifiers).

SUBSTANCE: cascade differential amplifier contains input parallel-balance cascade (1) on input transistors (2 and 3), bases of which are inputs (4 and 5) of cascade differential amplifier, and emitters are connected to supporting current supply (6), emitters of transistors (7,8 and 9) with combined bases are connected through current-stabilizing dipoles (10,11 and 12) to bus of first power supply (13), where emitter of transistor (7) is connected to collector of transistor (2), and emitter of transistor (8) is connected to collector of transistor (3), and collectors of transistors (7 and 8) are the first (14) and the second (15) outputs of cascade differential amplifier. Introduced also into circuit for increasing weakening coefficient of input cophased signal are additional transistors (16) and 17, bases of which are connected to corresponding bases of transistors (2) and (3), collectors are connected to emitter of transistor (9), emitters are connected to supporting current supply (6), where supporting current supply (6) is made on transistor (18), emitter of which is connected to bus of second current supply (19), base is connected to collector of transistor (9), and combined bases of transistors (7,8 and 9) are connected to additional shifting voltage supply (20).

EFFECT: increased efficiency.

2 cl, 6 dwg

Description

The invention relates to the field of radio engineering and communications and can be used as a device for amplifying analog signals in the structure of analog microcircuits for various functional purposes (for example, operational amplifiers (op amps)).

Known circuits of the so-called “bent” cascode differential amplifiers (DU) on npn and pnp transistors [1-35], which became the basis of more than 20 serial operational amplifiers manufactured as foreign (HA2520, NA5190, AD797, AD8631, AD8632, OP90 and etc.), and by Russian (154UD3, etc.) microelectronic companies. Due to the high popularity of such a remote control architecture, more than 200 patents have been issued for their modification. The present invention relates to this subclass of devices.

The closest prototype (figure 1) of the claimed device is the cascode differential amplifier (CDA) described in US patent No. 6456162 (figure 3), containing an input parallel-balanced cascade 1 on the first 2 and second 3 input transistors, the bases of which are inputs 4 and 5 cascode differential amplifiers, and the emitters are connected to the reference current source 6, the first 7, the second 8 and the third 9 output transistors with integrated bases, the emitters of which are connected through the first 10, second 11 and third 12 current-stabilizing two-terminal devices with the bus of the first 13 of the power source, and the emitter of the first output transistor 7 is connected to the collector of the first input transistor 2, the emitter of the second output transistor 8 is connected to the collector of the second input transistor 3, and the collectors of the first 7 and second 8 output transistors are the first 14 and second 15 outputs of the cascode differential amplifier .

A significant drawback of the known KDU (Fig. 1) is that it has a relatively small attenuation coefficient of the input common-mode signal (K _os.sf ), which negatively affects the errors of non-inverting decision amplifiers and comparators based on it.

The main objective of the invention is to increase the attenuation coefficient of the input common mode signal.

This goal is achieved by the fact that in the cascode differential amplifier (Fig. 1), containing an input parallel-balanced stage 1 at the first 2 and second 3 input transistors, the bases of which are inputs 4 and 5 of the cascode differential amplifier, and the emitters are connected to the reference current source 6, first 7, second 8 and third 9 output transistors with integrated bases, the emitters of which are connected through the first 10, second 11 and third 12 current-stabilizing two-terminal devices with the bus of the first 13 power supply, and the emitter of the first output the transistor 7 is connected to the collector of the first input transistor 2, the emitter of the second output transistor 8 is connected to the collector of the second input transistor 3, and the collectors of the first 7 and second 8 output transistors are the first 14 and second 15 outputs of the cascode differential amplifier, new elements and communications are provided in the circuit introduced the first 16 and second 17 additional transistors, the bases of which are connected to the corresponding bases of the first 2 and second 3 input transistors, the collectors are connected to the emitter of the third output about transistor 9, the emitters are connected to the reference current source 6, and the reference current source 6 is made on an auxiliary transistor 18, the emitter of which is connected to the bus of the second power source 19, the base is connected to the collector of the third 9 output transistor, and the combined bases of the first 7, second 8 and a third 9 output transistors are connected to an additional bias voltage source 20.

The amplifier circuit of the prototype is presented in figure 1. Figure 2 presents a diagram of the inventive device in accordance with claim 1 of the claims. Figure 3 shows the circuit cascode differential amplifier corresponding to claim 2 of the claims. Figures 4 and 5 show diagrams of the inventive (Fig. 5) and known (Fig. 4) devices in a computer simulation environment PSpice, and Fig. 6 shows frequency dependences of the attenuation coefficient of common-mode signals of the compared CDAs.

The differential amplifier (figure 2) contains an input parallel-balanced stage 1 on the first 2 and second 3 input transistors, the bases of which are inputs 4 and 5 of the cascode differential amplifier, and the emitters are connected to the reference current source 6, the first 7, the second 8 and the third 9 output transistors with integrated bases, the emitters of which are connected through the first 10, second 11 and third 12 current-stabilizing two-terminal circuits with the bus of the first 13 power supply, and the emitter of the first output transistor 7 is connected to the collector of the first input transistor 2, the emitter of the second output transistor 8 is connected to the collector of the second input transistor 3, and the collectors of the first 7 and second 8 output transistors are the first 14 and second 15 outputs of the cascode differential amplifier. The first 16 and second 17 additional transistors are introduced into the circuit, the bases of which are connected to the corresponding bases of the first 2 and second 3 input transistors, the collectors are connected to the emitter of the third output transistor 9, the emitters are connected to the reference current source 6, and the reference current source 6 is made on auxiliary transistor 18, the emitter of which is connected to the bus of the second power source 19, the base is connected to the collector of the third 9 output transistor, and the combined bases of the first 7, second 8 and third 9 output transistors are connected to additional source of bias voltage 20.

In a particular case, the first output 14 of the cascode differential amplifier (Fig. 3) is connected to the input 21 of the current mirror 22, the collector output of which 23 is connected to the second 15 output of the cascode differential amplifier and is the main output 24 of the cascode differential amplifier.

Consider the operation of the inventive cascode differential amplifier as an example of the analysis of the circuit of figure 2.

A significant drawback of the well-known KDUs is the insufficiently high common-mode signal attenuation, which substantially depends on the value of the output conductivity (for ₆ ) of the reference current sources 6 (IOT). For bipolar transistors, the output conductivity y6 depends on the Earley voltage (U _e ) and the static collector current (I _k18 ) of the transistor 18 as follows

For modern integrated transistors U _e = 20 ÷ 40 V, that is, at milliamp currents (I _k18 = 1 mA), the numerical values of the output resistance of the IOT are not large (R _out.6 = at ₆ ≈20 ÷ 40 kOhm), which negatively affects attenuation of common mode signals.

In the inventive device in the presence of an in-phase component of two signals u _c4 = u _c5 = u _{s the} current through the conductivity of ₆

For the emitter circuit of the input stage 1 (with identical transistors 2, 3, 16 and 17), we can compose the following system of equations

where β ₁₈ is the current gain of the base of the transistor 18 included in the structure of the reference current source 6.

Substituting the sum of currents (3) into equation (2), we can obtain that the increment of the total current of the emitter circuit of the input differential stage 1

Thus, in the circuit of FIG. 2, conditions are created under which the output currents of the KDU i _k8 (i _k7 ), due to the common-mode signal, are significantly weakened

Therefore, the output voltage of the KDU, due to the input common-mode signal, allocated, for example, at the load R _n1 , will be small

Therefore, the transfer coefficient of the common-mode signal from the input of the CDA to the output 14 in the claimed circuit is significantly

Since with identical static emitter currents of transistors 2 and 3 in the claimed and known CDD, the differential signal gain is the same, it follows that K _OS.sf in the circuit of FIG. 2 is N _c times better than in the circuit of FIG. 4, where N _with ≈β ₁₈ >> 1. These findings are confirmed by the results of computer simulations, which show that the proposed technical solution improves K _OS.sf more than an order of magnitude (28 dB).

BIBLIOGRAPHIC LIST

1. Matavkin V.V. High-speed operational amplifiers. - M.: Radio and Communications, 1989. - p. 74, fig. 4.15, p. 98, fig. 6.7.

2. US Patent No. 6218900, figure 1.

3. Patent application US 2002/0196079.

4. US patent No. 6788143.

5. US patent No. 3444838, figure 2.

6. US patent Re 30587.

7. Patent EP 1227580.

8. US patent No. 6714076.

9. US patent No. 5786729.

10. US Patent No. 5327100.

11. Patent application US 2004/0090268 A1.

12. US patent No. 4274061.

13. US patent No. 5422600, figure 2.

14. US patent No. 6788143, figure 2.

15. US patent No. 4959622, figure 1.

16. US patent No. 4406990, figure 4.

17. US patent No. 5418491.

18. US patent No. 6018268.

19. US Patent No. 5952882.

20. US patent No. 4723111.

21. US patent No. 4293824.

22. US patent No. 6580325.

23. US patent No. 6965266.

24. US patent No. 6867643.

25. US Patent No. 6236270.

26. US patent No. 5323121.

27. US patent No. 6229394.

28. US patent No. 5734296.

29. US patent No. 5477190.

30. US patent No. 5091701.

31. US patent No. 6717474.

32. US patent No. 6084475.

33. US patent No. 3733559.

34. Patent application US 2005/0001682 A1.

35. US patent No. 6300831.

Claims (2)

1. A cascode differential amplifier containing an input parallel-balanced cascade (1) on the first (2) and second (3) input transistors, the bases of which are the inputs (4) and (5) of the cascode differential amplifier, and the emitters are connected to the reference source current (6), first (7), second (8) and third (9) output transistors with integrated bases, the emitters of which are connected through the first (10), second (11) and third (12) current-stabilizing two-terminal devices with the bus of the first (13 ) a power source, the emitter of the first output transistor (7) connected to the call by the first input transistor (2), the emitter of the second output transistor (8) is connected to the collector of the second input transistor (3), and the collectors of the first (7) and second (8) output transistors are the first (14) and second (15) outputs of the cascode differential amplifier, characterized in that the first (16) and second (17) additional transistors are introduced into the circuit, the bases of which are connected to the corresponding bases of the first (2) and second (3) input transistors, the collectors are connected to the emitter of the third output transistor (9) emitters connected with a reference current source (6), and the reference current source (6) is made on an auxiliary transistor (18), the emitter of which is connected to the bus of the second power source (19), the base is connected to the collector of the third (9) output transistor, and the combined bases of the first (7), second (8) and third (9) output transistors are connected to an additional bias voltage source (20). 2. The device according to claim 1, characterized in that the first output (14) of the cascode differential amplifier is connected to the input (21) of the current mirror (22), the collector output of which (23) is connected to the second (15) output of the cascode differential amplifier and is the main output (24) of the cascode differential amplifier.

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