阅读说明：本技术 一种高频开关型移相器 (High-frequency switch type phase shifter ) 是由 赵涤燹 顾鹏 于 2019-11-22 设计创作，主要内容包括：本发明公开了一种高频开关型移相器,由5度移相单元、11度移相单元、22度移相单元、45度移相单元、90度移相单元构成,可以覆盖180度移相范围。所述的5度移相单元由开关电感移相结构实现,所述的11度移相单元、22度移相单元、45度移相单元、90度移相单元由优化T型移相结构实现。本发明提出了上述的开关电感移相结构和优化T型移相结构；基于该两种结构,进一步提出了移相单元的选取和排列策略,最终可实现低损耗、低移相附加衰减、宽带的移相效果。本发明为纯无源电路结构,无直流功耗,并支持正反双向移相；采用直接数字控制,相比基于数模转换(DAC)的模拟电压控制,具有时延低、反应快的优势。本发明适用于相控阵系统的移相器设计。(The invention discloses a high-frequency switch type phase shifter which is composed of a 5-degree phase shifting unit, an 11-degree phase shifting unit, a 22-degree phase shifting unit, a 45-degree phase shifting unit and a 90-degree phase shifting unit and can cover a 180-degree phase shifting range. The 5-degree phase shift unit is realized by a switched inductor phase shift structure, and the 11-degree phase shift unit, the 22-degree phase shift unit, the 45-degree phase shift unit and the 90-degree phase shift unit are realized by an optimized T-shaped phase shift structure. The invention provides the switch inductor phase shift structure and the optimized T-shaped phase shift structure; based on the two structures, selection and arrangement strategies of the phase shifting units are further provided, and finally, the phase shifting effects of low loss, low phase shifting additional attenuation and broadband can be realized. The invention is a pure passive circuit structure, has no direct current power consumption and supports positive and negative bidirectional phase shifting; compared with analog voltage control based on digital-to-analog conversion (DAC), the direct digital control has the advantages of low time delay and quick response. The phase shifter is suitable for designing the phase shifter of the phased array system.)

1. The high-frequency switch-type phase shifter is characterized by comprising a 90-degree phase shifting unit (100), a 22-degree phase shifting unit (200), a 5-degree phase shifting unit (300), an 11-degree phase shifting unit (400) and a 45-degree phase shifting unit (500) which are sequentially connected, wherein the 5-degree phase shifting unit (300) is of a switch inductor structure, and the 90-degree phase shifting unit (100), the 22-degree phase shifting unit (200), the 11-degree phase shifting unit (400) and the 45-degree phase shifting unit (500) are all optimized T-shaped structures.

2. A high frequency switch-type phase shifter according to claim 1, wherein said optimized T-type phase shifting structure is composed of a first transistor (101, 201, 401, 501), a second transistor (102, 202, 402, 502), a third transistor (103, 203, 403, 503), a first inductor (104, 204, 404, 504), a second inductor (105, 205, 405, 505), a third inductor (106, 206, 406, 506), and a first capacitor (107, 207, 407, 507), wherein: the source and drain of the first transistor (101, 201, 401, 501) are connected across the input and output terminals, and the gate is connected to a first digital signal (V)₉₀、V₂₂、V₁₁、V₄₅) (ii) a The gate of the second transistor (102, 202, 402, 502) is connected to the first digital signal (V)₉₀、V₂₂、V₁₁、V₄₅) The grid of the third transistor (103, 203, 403, 503) is connected with the second digital signal

3. A high-frequency switch-type phase shifter according to claim 1, wherein said switch-inductor phase shifting structure is composed of a fourth transistor (301) and a fourth inductor (302), wherein: the source and drain of the fourth transistor (301) are connected across the input and output terminals, and the gate is connected to the third digital signal (V)₅) (ii) a The fourth inductor (302) is connected in parallel with the source and the drain of the fourth transistor (301).

4. A high frequency switch-type phase shifter according to claim 2, wherein said second digital signal

5. A high frequency switch-type phase shifter according to claim 2, wherein the first inductance (104, 204, 404, 504) and the second inductance (105, 205, 405, 505) in each optimized T-shaped phase shifting structure have the same inductance value and are symmetric with respect to the vertical center of the optimized T-shaped phase shifting structure when laid out.

Technical Field

The invention relates to a high-frequency switch type phase shifter technology, belongs to the technical field of electronic circuit design, and is particularly suitable for phase shifter design in a phased array system.

Background

In recent years, with the rapid development of communication technology, communication frequencies have started to reach high frequencies of 6GHz or more. High frequency communications can provide a wide bandwidth but also introduce high losses. The phased array technology can compensate for the loss of high-frequency transmission and realize flexible signal coverage, and thus gradually becomes a key technology in applications such as satellite communication and millimeter wave 5G communication.

The phased array technology can realize high transmitting power by using a multi-antenna array to superpose transmitted electromagnetic waves in space; by adjusting the phase of the signals transmitted by each antenna, the beam direction can be adjusted, and efficient and flexible signal coverage can be realized. Therefore, the phase shifter for adjusting the phase becomes a key module of the phased array system.

The phase shifters in a phased array system should achieve the following: (1) broadband phase shifting to ensure that accurate beam pointing adjustment can be realized in the working frequency band; (2) the loss and the power consumption are low, so that the power consumption of a large-scale phased array system is reduced; (3) low phase-shifting additional loss to reduce amplitude deviation of each channel during phase shifting; (4) the control method is simple and quick, so that the control delay is reduced, and the reaction speed of the system is improved.

Compared with a GaAs process with high cost, the CMOS process has the advantages of low cost, low power consumption, high yield, large-scale production, easy integration with a CMOS digital circuit and the like, and is particularly suitable for application of low cost and low power consumption in mobile communication, so that the research on the design of a phase shifter based on the CMOS process is of great significance.

The switch type phase shifter realizes a wide range of phase adjustment by cascading multi-stage phase shift units. The single phase shift unit switches the phase shift state by the transistor switch so that the signal passes through the reference path or the phase shift path. Although the traditional inductance-capacitance-inductance T-shaped phase shift structure can realize the phase shift function at lower frequency, the performance of the traditional inductance-capacitance-inductance T-shaped phase shift structure cannot meet the design requirement of a high-frequency phase shifter.

Firstly, the traditional T-shaped phase shift structure can realize the phase shift of narrow bands, but obvious phase shift deviation occurs at the position deviated from the central frequency, and the requirement of broadband phase shift of a millimeter wave frequency band cannot be met; secondly, the conventional T-type phase shift structure usually introduces a large additional loss between the reference path and the phase shift path, resulting in different amplitude values in different phase states, which complicates the amplitude calibration of the phased array system; third, conventional high-phase-shift units (e.g., 90-degree units) often use two single-pole double-throw switches to switch the phase-shift state, which results in high insertion loss and is not favorable for low-power design of large-scale phased array systems.

Disclosure of Invention

In view of the above disadvantages, the present invention provides a 180-degree phase modulation range switch-type phase shifter with 5-bit direct digital control, which is suitable for CMOS process. The invention provides a switched inductor phase-shifting structure and an optimized T-shaped structure, and further provides selection and arrangement strategies of phase-shifting units based on the two structures, so that the phase-shifting effects of low loss, low phase-shifting additional attenuation and broadband can be realized finally.

In order to achieve the purpose, the invention adopts the following technical scheme:

a high-frequency switch-type phase shifter comprises a 90-degree phase shifting unit, a 22-degree phase shifting unit, a 5-degree phase shifting unit, an 11-degree phase shifting unit and a 45-degree phase shifting unit which are sequentially connected, wherein the 5-degree phase shifting unit is of a switch inductor structure, and the 90-degree phase shifting unit, the 22-degree phase shifting unit, the 11-degree phase shifting unit and the 45-degree phase shifting unit are all optimized T-shaped structures.

Furthermore, the optimized T-type phase shift structure is composed of a first transistor, a second transistor, a third transistor, a first inductor, a second inductor, a third inductor and a first capacitor, wherein: the source and the drain of the first transistor are bridged at the input end and the output end, and the grid is connected with the first digital signal; the grid electrode of the second transistor is connected with the first digital signal, and the grid electrode of the third transistor is connected with the second digital signal; the third inductor is connected in parallel with the source electrode and the drain electrode of the third transistor, the first capacitor is connected in parallel with the source electrode and the drain electrode of the second transistor, the source electrode of the third transistor and the common end of the third inductor are grounded, and the drain electrode of the third transistor and the common end of the third inductor are connected with the source electrode of the second transistor and the common end of the first capacitor in a terminating mode; the first inductor and the second inductor are connected in series and then connected in parallel to the source electrode and the drain electrode of the first transistor, and the common end of the first inductor and the second inductor is connected with the drain electrode of the second transistor and the common end of the first capacitor.

Further, the switched inductor phase shift structure is composed of a fourth transistor and a fourth inductor, wherein: the source and the drain of the fourth transistor are bridged at the input end and the output end, and the grid of the fourth transistor is connected with the third digital signal; the fourth inductor is connected in parallel with the source and the drain of the fourth transistor.

Further, the second digital signal is the inverse of the first digital signal.

Furthermore, the inductance value of the first inductor and the inductance value of the second inductor in each optimized T-shaped phase shifting structure are the same, and the optimized T-shaped phase shifting structures are symmetrical about the vertical center of the optimized T-shaped phase shifting structures during layout.

Advantageous effects

Compared with the prior art, the invention has the remarkable effects that:

firstly, the invention provides a switched inductor phase shifting structure which can reduce insertion loss;

secondly, the invention provides an optimized T-shaped phase shift structure, wherein on one hand, inductors ( inductors 106, 206, 406 and 506) are introduced to increase the phase shift broadband, and on the other hand, capacitors ( capacitors 107, 207, 407 and 507) are introduced to reduce the additional loss of the phase shift;

thirdly, the invention provides a selection and arrangement strategy of the phase shift unit, which can improve the impedance matching performance of the phase shift unit and reduce the insertion loss.

Drawings

Fig. 1 is a schematic diagram of a high-frequency switch-type phase shifter circuit.

Fig. 2 is a schematic diagram of a phase shifting structure of a switch inductor.

FIG. 3 is a schematic diagram of an optimized T-shaped phase shift structure.

Fig. 4 is a diagram showing the phase shift test results of a 5-bit switch-type phase shifter in CMOS process.

FIG. 5 is a diagram showing the phase shift accuracy test result of a 5-bit switch-type phase shifter in CMOS technology.

Fig. 6 is a graph of the amplitude deviation test results of a 5-bit switch-type phase shifter in CMOS process.

Detailed Description

To further illustrate the technical solutions disclosed in the present invention, the following detailed description is made with reference to the drawings and specific examples. Those skilled in the art will recognize that the preferred and improved embodiments of the present invention are possible without departing from the spirit of the present invention, and those skilled in the art will not be described or illustrated in detail in the present embodiment.

The application fields related to the phase shifter of the invention comprise: satellite communications, 5G communications, phased array systems, etc. Aiming at the defects of high loss, high phase-shift additional attenuation, narrow band and the like of the traditional structure in high frequency shift phase, the invention provides the switch inductance phase-shift structure and the optimized T-shaped phase-shift structure; based on the two structures, selection and arrangement strategies of the phase shifting units are further provided, and finally, the phase shifting effects of low loss, low phase shifting additional attenuation and broadband can be realized. The invention is a pure passive circuit structure, has no direct current power consumption and supports positive and negative bidirectional phase shifting; compared with analog voltage control based on digital-to-analog conversion (DAC), the direct digital control has the advantages of low time delay and quick response. The phase shifter is suitable for designing the phase shifter of the phased array system.

As shown in fig. 1, the high frequency switch-type phase shifter provided by the present invention comprises a 90-degree phase shift unit 100, a 22-degree phase shift unit 200, a 5-degree phase shift unit 300, an 11-degree phase shift unit 400, and a 45-degree phase shift unit 500, which are connected in sequence. Wherein, the 5-degree phase shift unit 300 adopts a switched inductor phase shift structure; the 90-degree phase shift unit 100, the 22-degree phase shift unit 200, the 11-degree phase shift unit 400 and the 45-degree phase shift unit 500 adopt an optimized T-shaped phase shifter structure. It should be noted here that the digital signal V₉₀、V₂₂、V₁₁、V₄₅The subscripts of (a) merely refer to the corresponding degree of phase shift, the digital signalAnd "-" in (b) indicates that the corresponding digital signal is inverted.

Fig. 2 shows the switched inductor phase shift structure, which is used for the 5-degree phase shift unit 300. The switched inductor phase shifting structure is composed of a transistor 301 and an inductor 302. The transistor 301 is connected across the input and output terminals and is supplied with a digital signal V₅Control, as a through path for the signal; the inductor 302 is connected across the input and output terminals as a phase shift path for the signal. By adjusting the inductance and quality factor of the inductor 302, this can be achieved5 degrees of phase switching is performed, and meanwhile, the loss of the phase shifter during the phase switching is kept consistent, namely, the additional loss of the phase shifting is zero. The switch inductor phase-shifting structure uses a single series transistor, so that the insertion loss can be effectively reduced; and the structure uses fewer devices, and can reduce the layout area of the phase shifter.

Fig. 3 shows the optimized T-type phase shift structure, taking the 90-degree phase shift unit 100 as an example, the 22-degree phase shift unit 200, the 11-degree phase shift unit 400, and the 45-degree phase shift unit 500 have the same structure, but the values of the specific device parameters are different. A transistor 101 connected across the input and output terminals and receiving a digital signal V₉₀A control as a through path for the input signal; transistor 102, transistor 103, inductor 104, inductor 105, capacitor 107 connected in parallel with transistor 102, and inductor 106 connected in parallel with transistor 103 form a phase shift path for an input signal. The transistor 102 is formed by a digital signal V₉₀Control, transistor 103 is controlled by a digital signal

And (5) controlling. When the digital signal V₉₀At high, transistor 101 and transistor 102 are turned on, transistor 103 is turned off, and inductor 106 resonates with the parasitic capacitance of transistor 103 which is turned off, and the input signal is passed through to the output terminal. When the digital signal V₉₀When the voltage level is low, the transistor 101 and the transistor 102 are turned off, the transistor 103 is turned on, and the inductor 104, the inductor 105, the parasitic capacitance of the transistor 102, the capacitor 107, the transistor 103, and the inductor 106 form a T-type phase shift network. Due to the parasitic capacitance, the transistors will introduce additional loss of phase shifting when switching between on and off for the phase shifting unit. Optimizing the T-shaped phase shifting structure reduces the phase shifting parasitic loss by jointly adjusting transistor 102 and capacitor 107 in parallel with transistor 102. The phase shift bandwidth will be limited due to the naturally narrow-band nature of the inductor-capacitor-inductor network. The optimized T-shaped phase shift structure increases the phase shift bandwidth by adjusting transistor 103 and inductor 107 in parallel with transistor 106.

FIG. 4 shows the phase shift performance test results of the 5-bit 180-degree phase shifter of the present invention, wherein the operating frequency is 24-30GHz, the phase shift operation of the 5-bit controlled 180-degree phase shift range is realized, and 32 phase states are basically non-overlapped. It can be known that the phase shifter realizes the effect of broadband phase shift.

FIG. 5 shows the phase shift precision test results of the 5-bit 180-degree phase shifter of the present invention, wherein the root mean square error of the phase shift is less than 6 degrees in the 24-30GHz working frequency band. At the central frequency of 27GHz, the root mean square error of the phase shift is about 3.5 degrees, which shows that the phase shifter realizes the high-precision phase shift.

FIG. 6 shows the result of the amplitude deviation test of the 5-bit 180-degree phase shifter of the present invention, wherein the root mean square error of the amplitude is less than 0.6dB in the 24-30GHz working frequency band. At the central frequency of 27GHz, the amplitude root mean square error is less than 0.1dB and is about 0.07dB, which means that the phase shifter greatly reduces the additional loss of phase shift.