RU2475946C1 - Ac amplifier with antiphased current outputs - Google Patents

Abstract

FIELD: radio engineering, communication.

SUBSTANCE: in the amplifier the base of the first output transistor is connected with its emitter and input (6) of the device, which via an input current source is connected with the second bus of a power supply source, the collector of the first input transistor is connected with a non-inverting current output of the device matched with the first bus of the power supply source, the emitter of the first output transistor via an additional current source is connected with the second bus of the power supply source, and via a correcting capacitor it is connected to a non-inverting current output of the device.

EFFECT: provision of matching of anti-phased current outputs with one bus of power supply sources.

5 cl, 14 dwg

Description

The invention relates to the field of radio engineering and communication and can be used as a functional unit of various variable signal amplification devices in the structure of analog microcircuits of various functional purposes (for example, broadband amplifiers, comparators, phase splitters, etc.).

The basis of most modern operational amplifiers, voltage stabilizers, comparators are the so-called "current mirrors" (current repeaters) [1-79]. In the patent literature, these devices with the same functional purpose are present in the class H03F, as well as classes G05F, H03K IPC. Qualitative indicators of many analog devices are determined by the dynamic parameters of current mirrors. This explains the large number of patents devoted to this subclass of functional units [1-79].

The closest prototype of the claimed device is an AC amplifier (UT) (figure 1), presented in the patent of Analog Devices US 6.677.807, fig.1. It contains the first 1 input transistor, the base of which is connected to the collector, the first 2 output transistor, the collector of which is an inverting current output 3 of the device, matched with the first 4 bus of the power source, an input current source 5 connected to the input 6 of the device, non-inverting current output 7 devices, the second 8 bus power supply.

A significant drawback of the known CT is that it has asymmetrical antiphase current outputs that are matched with different buses of power supplies (4, 8), which limits its use as current phase splitters of the input single-phase signal - the so-called “baluns” (buluns).

The main objective of the invention is to “link” the antiphase current outputs of the device to one (first 4) bus of power sources.

An additional task is the formation on the basis of the claimed UT (figure 1) of a selective amplifier with a resonant amplitude-frequency characteristic (AFC).

The tasks are solved in that in the current amplifier containing the first 1 input transistor, the base of which is connected to the collector, the first 2 output transistor, the collector of which is an inverting current output 3 of the device, matched with the first 4 bus of the power source, input current source 5, connected with device input 6, non-inverting current output of device 7, second 8 power supply bus, new elements and communications are provided - the base of the first 2 output transistor is connected to the emitter of the first 1 input trans the torus and the input 6 of the device, which is connected through the input current source 5 to the second 8 bus of the power source, the collector of the first 1 input transistor is connected to the non-inverting current output 7 of the device, matched with the first 4 bus of the power source, the emitter of the first 2 output transistor through an additional current source 9 is connected to the second 8 bus of the power source and through a correction capacitor 10 is connected to a non-inverting current output 7 of the device.

The scheme of the UT-prototype is shown in the drawing of Fig. 1, and in the drawing of Fig. 2 shows a variant of its typical inclusion in the structure of a differential amplifier that performs the functions of an input current source for the claimed device.

The diagram of the inventive device in accordance with claim 1 and claim 2 of the claims is shown in the drawing of figure 3.

The drawing of figure 4 shows a diagram of the UT in accordance with paragraph 3 of the claims.

The drawing of figure 5 presents a diagram of the UT in accordance with paragraph 4 of the claims.

The drawing of Fig.6 shows a diagram of UT according to claim 5 of the claims.

In the drawings of Fig.7 and Fig.8 shows a circuit UT in the structure of differential amplifiers, characterizing the use of the claimed device.

и 7(Вых.i₁) (out_i₁, out_i₂, фиг.9).In the drawings of Fig.9 shows a diagram of the claimed UT (Fig.3) in the Cadence computer simulation environment on models of SiGe transistors, and in the drawing of Fig.10 - its frequency dependence of the current gain of the UT from input 6 to outputs

and 7 (Out. i ₁ ) (out_i ₁ , out_i ₂ , Fig. 9).

The drawing of Fig.11 shows a diagram of the UT of Fig.6 in the computer simulation environment of Cadence on models of SiGe transistors.

The drawing of Fig. 12 shows the frequency dependence of the current transfer coefficients K _i from the input of the device to the outputs out1 and out2 of the CT of Fig. 11 with the capacitance of the correction capacitor 10 C ₁₀ = C = 10 nF.

The drawing of Fig.13 shows a diagram of the current amplifier of Fig.6 in the microwave mode of the selective amplifier at C ₁₀ = C = 1 pF.

The drawing of Fig. 14 shows the frequency dependence of the current transfer coefficients K _{i of} UT of Fig. 13 to outputs out1 and out2 in the mode of a selective microwave amplifier with the capacitance of a correction capacitor 10 C ₁₀ = C = 1 pF.

The AC amplifier with antiphase current outputs of Fig. 3 contains a first 1 input transistor, the base of which is connected to the collector, a first 2 output transistor, the collector of which is an inverting current output 3 of the device, matched with the first 4 bus of the power source, input current source 5, connected with the input 6 of the device, non-inverting current output 7 of the device, the second 8 bus power source. The base of the first 2 output transistor is connected to the emitter of the first 1 input transistor and the input 6 of the device, which is connected through the input current source 5 to the second 8 bus of the power source, the collector of the first 1 input transistor is connected to a non-inverting current output of the device 7, matched with the first 4 source bus power, the emitter of the first 2 output transistor through an additional current source 9 is connected to the second 8 bus of the power source and through a correction capacitor 10 is connected to a non-inverting current output 7 device.

In the drawing of figure 3, in accordance with claim 2, the first 2 output transistor is made in the form of a composite transistor containing m ₂ ≥1 bipolar transistors connected in parallel.

In the drawing of FIG. 4, in accordance with claim 3, the non-inverting current output 7 of the device is connected to the emitter of the first 11 additional transistor, the base of which is connected to the auxiliary voltage source 12, and the collector is connected to an additional non-inverting current output 13 of the device, consistent with the first 4 bus power supply. The outputs 3 and 13 of the device can be connected with load resistors 14 and 15.

In the drawing of Fig. 5, in accordance with claim 4, the inverting current output 3 of the device is connected to the emitter of the second 16 additional transistor, the base of which is connected to the base of the first 11 additional transistor, and the collector is connected to the additional inverting current output 17 of the device.

In the drawing of FIG. 6, in accordance with claim 5, the first 11 additional transistor is made in the form of m ₂ auxiliary bipolar transistors connected in parallel (via emitter-base junctions), and the collectors m ₂ -1 are auxiliary bipolar transistors in the structure of the first 11 an additional transistor is connected to an additional non-inverting output 13 of the device, and the collector m of the _2nd auxiliary bipolar transistor is connected to the first 4 bus of the power source, where m ₂ is the number of bipoles connected in parallel transistors in the structure of the first 2 output transistor.

In the circuit of Fig. 7, the functions of the input current source 5 and the additional current source 9 are performed by the current outputs of the voltage-current converter PNT1, for example, a differential stage. This diagram shows one of the areas of practical use of the claimed device.

An example of a practical implementation of the amplifier of Fig. 7 is given in the drawing of Fig. 8, in which a current source 18 is used as a dynamic load in the output circuit 3.

Consider the work of the claimed UT figure 3.

At high frequencies, when the influence of the reactance of the capacitance of the capacitor 10 can be neglected, when the input current of the device changes by the value of i _in currents through the emitter junctions of transistors 1 and 2, as well as the currents of outputs 3 and 7:

where m ₂ is the number of parallel-connected transistors forming a composite transistor 2 for which the emitter-base _voltage is u _eb . ₂ = u _eb . ₁ .

Thus, the current transfer coefficients of the UT of FIG. 3 to output 3 (K _i3 ) and output 7 (K _i7 ):

From the formulas (4) and (5) it follows that in the claimed device 3 functions implemented fazorasschepitelya-phase input signal (i _Rin) from the current outputs 3 and 7, "attached" to one (a first) power source bus 4, which substantially expands the scope of its practical use. However, K _i3 ≠ K _i7 .

These theoretical conclusions are confirmed by the results of modeling schemes of Fig.9, Fig.11, Fig.13.

The introduction of the transistor 11 in accordance with the drawing of figure 4 provides a sufficiently high value of the output impedance UT for outputs 3 and 13.

In the circuit of FIG. 5, transistors 16 and 11 provide cascode (i.e., higher frequency) transmission of input current to outputs 17 and 13.

The introduction of the transistor 11 in accordance with paragraph 5 of the claims (Fig.6) solves the problem of "alignment" of the current gain for the inverting (K _i13 ) and non-inverting (K _i17 ) outputs of the UT ( _{Fig.12, Fig.14} ). In this case, due to the multi-collector transistor 11, the equality K _i13 = K _{i17 is ensured} :

Indeed, a comparison of the graphs of Fig. 10 and Fig. 12 (Fig. 14) shows a fairly high identity of the transmission of the input current signal to the antiphase outputs 17 and 13 of the device to frequencies of 10-15 GHz. Moreover, due to the choice of the capacitance of the correction capacitor 10, a resonant view of the amplitude-frequency characteristic is realized (Fig. 14).

Thus, the claimed UT has two antiphase current outputs, coordinated with the bus of a positive power source, and, in addition, is characterized by the properties of a resonant amplifier with K _i > 1. These properties of the UT make it possible to implement on its basis analog signal mixers based on Hilbert cells.

BIBLIOGRAPHIC LIST

1. Volovich G.I. Circuitry of analog and analog-to-digital electronic devices, 2nd ed., Rev. - M.: Dodeka - XXX1 Publishing House, 2007. - 528 p., Ill., P. 21, fig. 7.9.

2. RF patent №1.329.639

3. US Patent No. 3,681.623

4. US Patent No. 3,813.607

5. US Patent No. 3,835,410

6. US Patent No. 4.008.441, H03f 3/16

7. US Patent No. 4.013.973

8. US patent No. 4.030.044 (figure 3)

9. US Patent No. 4,095.189

10. US Patent No. 4.117.417

11. US Patent No. 4,241.315

12. US Patent No. 4,345.213

13. US Patent No. 4,412.186, H03f 3/04

14. US Patent No. 4,471.236

15. US patent No. 4.591.804, H03f 3/04

16. US Patent No. 4,769.619

17. US Patent No. 4,855.686

18. US Patent No. 4,937.515 G05f 3/26

19. US Patent No. 4,990.864

20. US Patent No. 5.053.718

21. US patent No. 5.079.518 H03K 3/16

22. US Patent No. 5.164.658

23. US Patent No. 5,373.253

24. US Patent No. 5,399.991

25. US Patent No. 5,572.114

26. US Patent No. 5,969.574

27. US patent No. 5.986.507

28. US patent No. 6.016.050

29. US Patent No. 6,570,438

30. US patent No. 6.573.795

31. US Patent No. 6,586.918

32. US patent No. 6.606.001

33. US patent No. 6.300.803

34. US Patent No. 6,528.981

35. US Patent No. 6,630.818

36. US Patent No. 6,639.452

37. US patent No. 6.677.807

38. US Patent No. 6,680.605

39. US Patent Application 2006/0033577, fig.4

40. US patent 5.157.322, fig.4

41. US patent application 2003/0030492, fig.1

42. US patent 6.633.198, fig.1

43. US Patent 4,057,763

44. US patent No. 6.657.481, fig.2

45. US patent No. 6.573.795, fig. 1

46. US Patent No. 6,680.651, fig. 1

47. US Patent No. 6,291.977, fig.1a

48. US patent No. 4.733.161, fig.1

49. US patent No. 4.897.614, fig.1b

50. US Patent No. 5,933.055, fig. 4c

51. US Patent No. 4,567,444, fig. 1

52. US Patent No. 5,512.815, fig. 1c

53. US patent No. 4.031.456, fig.1

54. US Patent No. 4,300.091, fig. 10

55. US patent No. 4.345.217, fig.1

56. US Patent No. 3,921.013, fig.2

57. US patent No. 5.132.640, fig.1

58. US Patent No. 5,394.079, fig. 1

59. US patent No. 4.158.178, fig.2

60. US Patent No. 3,952.257, fig. 1

61. US Patent No. 3,588.672, fig.6

62. US patent No. 3320.439

63. US patent No. 4.879.524, fig.1

64. US Patent No. 6,586.918

65. US Patent Application 2005/021894

66. US Patent Application 2010/0127765, fig. 1

67. US Patent No. 4,536,702, fig. 1

68. US Patent No. 5,633.612, fig. 1

69. US Patent No. 4,462.005, fig. 1

70. US Patent No. 4,528,496, fig. 1

71. US Patent No. 4,473,794, fig. 5

72. US Patent No. 5,721.512, fig. 1

73. US patent No. 6.816.014, fig.1

74. US Patent No. 3,979.606, fig. 1

75. US Patent No. 5,357.188, fig. 5

76. US patent No. 6.191.656

77. US patent No. 5.291.149, fig.5

78. RF patent 2193273

79. US patent application 2004/081688

Claims (5)

1. An AC amplifier with antiphase current outputs, comprising a first (1) input transistor, the base of which is connected to the collector, a first (2) output transistor, the collector of which is an inverting current output (3) of the device, matched with the first (4) source bus power supply, input current source (5), connected to the input (6) of the device, non-inverting current output (7) of the device, the second (8) bus of the power source, characterized in that the base of the first (2) output transistor is connected to the emitter of the first (1 ) input the resistor and the input (6) of the device, which is connected through the input current source (5) to the second (8) bus of the power source, the collector of the first (1) input transistor is connected to the non-inverting current output (7) of the device, matched with the first (4) bus the power source, the emitter of the first (2) output transistor is connected via an additional current source (9) to the second (8) bus of the power source and is connected to the non-inverting current output (7) of the device through a correction capacitor (10). 2. An AC amplifier with antiphase current outputs according to claim 1, characterized in that the first (2) output transistor is made as a composite transistor containing m ₂ ≥1 bipolar transistors connected in parallel. 3. An AC amplifier with antiphase current outputs according to claim 1, characterized in that the non-inverting current output (7) of the device is connected to the emitter of the first (11) additional transistor, the base of which is connected to the auxiliary voltage source (12), and the collector is connected to additional non-inverting current output (13) of the device, consistent with the first (4) bus power source. 4. An AC amplifier with antiphase current outputs according to claim 3, characterized in that the inverting current output (3) of the device is connected to the emitter of the second (16) additional transistor, the base of which is connected to the base of the first (11) additional transistor, and the collector is connected with an additional inverting current output (17) of the device. 5. An AC amplifier with antiphase current outputs according to claim 4 or 2, characterized in that the first (11) additional transistor is made in the form of m ₂ auxiliary bipolar transistors connected in parallel along emitter-base junctions, and the collectors m ₂ -1 are auxiliary bipolar transistors in the structure of the first (11) additional transistor are connected to an additional non-inverting output (13) of the device, and the collector m _{2 of the} auxiliary bipolar transistor is connected to the first (4) bus of the power source, where m ₂ - the number of parallel-connected bipolar transistors in the structure of the first (2) output transistor.

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