JP7287349B2 - Radar circuit unit, radar equipment - Google Patents

Description

The present disclosure relates to a radar circuit unit and a radar device.

2. Description of the Related Art As disclosed in Patent Literature 1, a radar device for detecting an object using reflected waves of radar waves is widely known. In such a radar device, a transmission signal that is converted and output to a radar wave by a transmission antenna is generated based on a frequency-controlled modulated signal.

JP 2019-184339 A

The radar device disclosed in Patent Document 1 employs a radar circuit unit that amplifies a modulated signal with an amplifier and generates a transmission signal. However, since transistors forming an amplifier generally have a withstand voltage limit, the amplitude of the modulation signal may exceed the withstand voltage limit.

Therefore, a method of dividing the power of the modulated signal into a plurality of branch signals, suppressing the amplitude below the withstand voltage limit, and synthesizing them with a passive element such as a balun having no withstand voltage limit is conceivable. However, in this method, the power loss increases at the stage where the power of the high-frequency modulated signal matched with the radar wave is distributed to each branch signal. This is because a long metal wiring is required for power distribution of the radar circuit unit, and the power loss of the metal wiring increases as the frequency increases due to the skin effect. As a result, especially in the amplification stage before power distribution, the amplification factor must be increased in advance, resulting in an increase in power consumption.

An object of the present disclosure is to provide a radar circuit unit and a radar device that reduce power consumption.

Technical means of the present disclosure for solving the problems will be described below. It should be noted that the symbols in parentheses described in the claims and this column indicate the correspondence with specific means described in the embodiments described in detail later, and limit the technical scope of the present disclosure. not something to do.

A first aspect of the present disclosure is
A radar circuit unit (4) for generating a transmission signal (Ss) converted and output to a radar wave by a transmission antenna (2) based on a frequency-controlled modulated signal (Sl),
a power divider (22) for power-dividing a modulated signal with a frequency lower than that of a radar wave into a plurality of branch signals;
a plurality of multipliers (23) for individually frequency-multiplying each of the branched signals, the power of which is divided by the power divider, in accordance with the radar wave;
a plurality of power amplifiers (24) for individually amplifying the branched signals frequency-multiplied by each multiplier;
a power combiner (25) that combines the branched signals amplified by each power amplifier into a transmission signal;
Prepare.

A second aspect of the present disclosure is
a radar circuit unit of the first aspect;
a transmission antenna that converts a transmission signal generated by the radar circuit unit into a radar wave and outputs the signal;
A radar device comprising

In these first and second aspects, the branch signals, which are power-divided at a stage lower than the radar wave, are individually frequency-multiplied to match the radar wave, and then individually amplified before being combined into the transmission signal. be. According to this, the power loss is reduced at the stage where the power of the low-frequency modulated signal is distributed to each branch signal. This is because the power loss due to the skin effect is smaller at low frequencies than at high frequencies. Therefore, by distributing power at low frequencies, it is possible to reduce power consumption by suppressing the amplification factor for each branched signal in the amplification stage after frequency multiplication.

1 is a block diagram showing the basic configuration of a radar device according to first and second embodiments; FIG. It is a block diagram which shows the basic composition of the radar circuit unit among the radar apparatuses by 1st and 2nd embodiment. 3 is a block diagram showing a specific example of the radar circuit unit shown in FIG. 2; FIG. 3 is a block diagram showing the detailed configuration of a radar circuit unit in the radar device according to the first embodiment; FIG. It is a block diagram which shows the radar circuit unit of a comparative example. 7 is a graph for explaining the effects of the radar device and the radar circuit unit according to the first embodiment in comparison with a comparative example; It is a block diagram which shows the detailed structure of the radar circuit unit among the radar apparatuses by 2nd embodiment.

A plurality of embodiments will be described below with reference to the drawings. Note that redundant description may be omitted by assigning the same reference numerals to corresponding components in each embodiment. When only a part of the configuration is described in each embodiment, the configurations of other embodiments previously described can be applied to other portions of the configuration. Moreover, not only the combinations of the configurations explicitly specified in the description of each embodiment, but also the configurations of a plurality of embodiments can be partially combined even if they are not specified unless there is a particular problem with the combination.
(basic configuration)
First, the basic configuration of the first and second embodiments, which will be detailed later, will be described.

A radar device 1 whose basic configuration is shown in FIG. 1 detects an object by utilizing reflected waves of radar waves. The radar device 1 is mounted, for example, on a moving object such as a vehicle. The radar device 1 is mainly composed of a semiconductor integrated circuit device such as MMIC (Monolithic Microwave Integrated Circuit). The radar device 1 includes a transmitting antenna 2 , a receiving antenna 3 and a radar circuit unit 4 .

The transmission antenna 2 converts the transmission signal Ss generated by the radar circuit unit 4 into a radar wave and outputs the radar wave. At this time, the radar wave is output at a frequency f in the millimeter wave band such as 76 GHz. The receiving antenna 3 converts a reflected radar wave reflected by an object into a received signal Sr and inputs the received signal Sr to the radar circuit unit 4 . The radar circuit unit 4 is electrically connected with the transmitting antenna 2 and the receiving antenna 3 . The radar circuit unit 4 includes a control section 10 , a transmission section 20 (see also FIGS. 2 and 3), and a reception section 30 .

The control unit 10 has a PLL (Phase Locked Loop) 12 . The control unit 10 performs frequency control such as FCM (Fast-Chirp Modulation) modulation using the PLL 12 to generate a local signal Sl having a frequency lower than that of the radar wave as a modulated signal. At this time, the frequency of the local signal Sl is modulated to a value that is 1/N (that is, f/N) of the frequency f of the radar wave, where N is a natural number of 2 or more. The control unit 10 inputs the local signal Sl frequency-controlled by the PLL 12 to the transmission unit 20 and the reception unit 30 .

As shown in FIGS. 2 and 3, the transmission unit 20 receives the local signal Sl from the PLL 12 . The transmission section 20 has a preamplifier 21 , a power divider 22 , a multiplier 23 , a power amplifier 24 and a power combiner 25 . The transmission unit 20 distributes the power of the local signal Sl that has been passed through the preamplifier 21 and amplified by the power divider 22, thereby generating a plurality of branched signals Sb. Here, the number of branches of the branch signal Sb is represented by 2 raised to the i-th power (that is, 2 ⁱ ), where i is a natural number.

The transmission unit 20 individually frequency-multiplies each of the branched signals Sb to which power is distributed by the power divider 22 using a plurality of corresponding multipliers 23 . Here, the number of multipliers 23 is the same as the number of branches of the branch signal Sb, and is defined by 2 raised to the i power (that is, 2 ⁱ ). Also, the multiplication ratio of the frequency f of the radar wave is defined by N with respect to the frequency f/N of the local signal Sl. In addition, 2 ⁱ and N are set to values that match or differ. Under these definitions and settings, the 2 ⁱ multipliers 23 each convert the branch signal Sb into a signal of frequency f multiplied by N. In particular, FIG. 2 corresponds to the first and second embodiments described in detail later, and shows a specific example of the radar circuit unit 4 in which both the values of ²ⁱ and N are two.

As shown in FIGS. 2 and 3, the transmission unit 20 individually amplifies each branch signal Sb frequency-multiplied by each multiplier 23 with a plurality of corresponding power amplifiers 24 . Each power amplifier 24 is mainly composed of at least one transistor. Here, the number of power amplifiers 24 is the same as the number of branches of the branched signal Sb and the number of multipliers 23, and is defined by the i power of 2 (that is, 2 ⁱ ). Under this definition, the 2 ⁱ power amplifiers 24 each amplify the N-multiplied branch signal Sb of the frequency f with a predetermined amplification factor. Therefore, in each power amplifier 24, the amplification factor is preset so that the amplitude of the branch signal Sb is less than the withstand voltage limit of the transistor constituting each power amplifier.

The transmitting section 20 combines each branch signal Sb amplified by each power amplifier 24 into a transmission signal Ss by a common power combiner 25 . The transmission signal Ss generated by this synthesis is output from the power combiner 25 to the transmission antenna 2 and converted into a radar wave having substantially the same frequency f as the transmission signal Ss.

As shown in FIG. 1 , a reception signal Sr from the reception antenna 3 and a local signal Sl from the PLL 12 are input to the reception section 30 for the transmission section 20 . The receiving section 30 has a mixer 32 and a receiving amplifier 34 . The receiver 30 mixes the reception signal Sr and the local signal Sl with the mixer 32 and then amplifies the mixed signal with the reception amplifier 34 . Therefore, the controller 10 calculates the distance to the object based on the amplified signal from the receiver 30 .

(First embodiment)
Next, the detailed configuration of the first embodiment will be described. As shown in FIG. 4, the power divider 22 of the first embodiment is a cascode branch circuit in which a plurality of differential amplifiers 222 and transformers 224 are combined with a common differential divider 220 . Here, in the first embodiment, i=1 and the branch number ²ⁱ of the branch signal Sb is set to 2, which is the same as the multiplication ratio N (see FIGS. 2 and 3). A pair of differential amplifiers 222 and transformers 224 are provided according to this setting.

The differential divider 220 is provided with positive and negative input terminals INP and INN. A local signal Sl as a modulated signal amplified by the preamplifier 21 (see FIG. 3) is input to these input terminals INP and INN. Here, the frequency of the local signal Sl is controlled to a value represented by f/2 (that is, a half value of f), for example, 38 GHz, where the multiplication ratio N for the frequency f of the radar wave is 2.

The differential divider 220 is provided with a pair of power transistors 220a and 220b, which are field effect transistors such as MOSFETs (metal-oxide-semiconductor field effect transistors). Gates of the power transistors 220a and 220b are individually connected to corresponding input terminals INP and INN, respectively. The sources of power transistors 220a and 220b are grounded. The drains of the power transistors 220a and 220b are branched and connected to both differential amplifiers 222 in the latter stage.

With such a configuration, the differential distributor 220 amplifies the differentially input local signal Sl and branches it to each differential amplifier 222, thereby distributing power to the branched signals Sb to each of these differential amplifiers 222. FIG. As a result, a branch signal Sb whose frequency is substantially held at f/2 and whose current is substantially halved (that is, about 1/2) is input to each differential amplifier 222 .

Each differential amplifier 222 is provided with a pair of power transistors 222a and 222b, which are field effect transistors such as MOSFETs. A power supply voltage VDD is applied to gates of the power transistors 222a and 222b. The sources of the power transistors 222a and 222b are individually cascode-connected to the corresponding drains of the power transistors 220a and 220b in the differential divider 220 in the preceding stage. The drains of the power transistors 222a and 222b are individually connected to the corresponding subsequent transformers 224, respectively.

Each transformer 224 is of a center-tap type in which power supply voltage VDD is applied to the coupling midpoint between each pair of primary coils 224a. The input ends of a pair of primary coils 224a in each differential transformer 224 are individually connected to the drains of the corresponding power transistors 222a and 222b. Each output end of each pair of secondary coils 224b in each transformer 224 is individually connected to the corresponding post-stage multiplier 23 .

Due to these configurations, each differential amplifier 222 receives a branch signal Sb whose power is distributed by the differential distributor 220 under stable power supply from the corresponding transformer 224 . Each differential amplifier 222 amplifies the input branch signal Sb at the frequency f/2 while the parasitic capacitance of the power transistors 222 a and 222 b is reduced by the inductor function of the corresponding transformer 224 . The branch signal Sb amplified by each differential amplifier 222 is input to the corresponding multiplier 23 through the secondary coil 224b of the corresponding transformer 224. FIG.

Each multiplier 23 is a differential frequency multiplier circuit that receives an input from a corresponding pair of secondary coils 224b of the power divider 22 in the preceding stage. A pair of output terminals of each multiplier 23 is individually connected to a corresponding power amplifier 24 in the subsequent stage. The branched signal Sb power-divided by the power divider 22 is differentially input to each multiplier 23 having such a configuration in an amplified state. Each multiplier 23 as a doubler having a multiplication ratio N of 2 doubles the frequency f/2 of the amplified input branch signal Sb. As a result, each multiplier 23 inputs to the corresponding power amplifier 24 the branch signal Sb with the frequency f increased in accordance with the radar wave.

Each power amplifier 24 is a differential amplifier circuit that receives an input from the corresponding pre-stage multiplier 23 . Each power amplifier 24 is provided with a pair of power transistors 240a and 240b, which are field effect transistors such as MOSFETs. Gates of the power transistors 240a and 240b are individually connected to output terminals of the corresponding multipliers 23, respectively. The sources of power transistors 240a and 240b are grounded. The drains of the power transistors 240a and 240b are commonly connected to the power combiner 25 in the subsequent stage. A capacitor 240c for suppressing oscillation is interposed between the gate of the power transistor 240a and the drain of the power transistor 240b and between the gate of the power transistor 240b and the drain of the power transistor 240a. Note that the capacitor 240c may be omitted.

A branch signal Sb frequency-multiplied by a corresponding multiplier 23 is differentially input to each power amplifier 24 having such a configuration while stable power is supplied from a power combiner 25, which will be described in detail later. Each power amplifier 24 amplifies the input branch signal Sb with the frequency f as it is, and inputs it to the common power combiner 25 .

The power combiner 25 is a passive balun combining circuit that receives inputs from the power amplifiers 24 in the previous stage. Power combiner 25 is configured by a combination of transformers 250 and 251 . Each of the transformers 250 and 251 is of a center-tap type in which a power supply voltage VDD is applied to the coupling midpoint between each pair of primary coils 250a and 251a.

The input terminal of each primary coil 250a in the first transformer 250 is individually connected to the drain of the power transistor 240a in the corresponding power amplifier 24 in the previous stage. The input terminal of each primary coil 251a in the second transformer 251 is individually connected to the drain of the power transistor 240b in the corresponding power amplifier 24 in the previous stage.

Each pair of coupling ends of the secondary coils 251b in the first transformer 250 and each pair of coupling ends of the secondary coils 251b in the second transformer 251 are coupled to correspond to each other. The output end of one secondary coil 251b in the second transformer 251 is grounded. The output end of the other secondary coil 251 b in the second transformer 251 is connected to the output terminal OUT provided in the power combiner 25 .

The power combiner 25 having such a configuration receives the branch signal Sb of frequency f amplified by each power amplifier 24 under stable power supply to each power amplifier 24 . The power combiner 25 generates a transmission signal Ss having a frequency f by synthesizing the amplitudes of the input branch signals Sb while aligning the positive and negative phases.

(Effect)
The effects of the first embodiment described above will be described below.

In the first embodiment, the branch signal Sb, which is power-divided from the local signal Sl as a modulated signal with a frequency lower than that of the radar wave, is individually frequency-multiplied in accordance with the radar wave, and then is combined into the transmission signal Ss. are amplified separately. According to this, the power loss is reduced at the stage where the power of the low-frequency local signal Sl is distributed to each branch signal Sb. As a result, it is possible to reduce power consumption by suppressing the amplification factor for each branch signal Sb and the like, particularly in the amplification stage after power distribution and frequency multiplication, and also in other amplification stages.


The branch signals Sb, which are power-divided at a stage lower than the radar wave, are individually frequency-multiplied to match the radar wave, and then individually amplified before being combined into the transmission signal Ss. According to this, power loss is reduced at the stage where the power of the local signal Sl, which is a low-frequency modulated signal, is distributed to each branch signal Sb. This is because the power loss due to the skin effect is smaller at low frequencies than at high frequencies. Therefore, if power is distributed at low frequencies, power consumption can be reduced by suppressing the amplification factor for each branch signal Sb and the like in the amplification stage after frequency multiplication and in other amplification stages. .

Here, a comparative example shown in FIG. 5 will be described with respect to the first embodiment shown in FIG. In the comparative example, after the local signal Sl of frequency f/2 passed through the preamplifier 51 is doubled by the multiplier 52, the power divided by the power divider 53 and the branch signal Sb of the frequency f is amplified by the power amplifier 54, A power combiner 55 combines them into a transmission signal Ss. Such a comparative example has the above-mentioned problem inherently. On the other hand, the first embodiment can exhibit the effect of reducing power consumption, as is clear from FIG.

Further, according to the first embodiment, the power divider 22 that distributes the power of the local signal Sl as a modulated signal into a plurality of branched signals Sb is a cascode power divider 220 that is a combination of a differential divider 220 and a plurality of differential amplifiers 222. It is a branch circuit. Such a cascode branch circuit can minimize power loss associated with power distribution between the differential divider 220 and each differential amplifier 222 . Therefore, it is possible to secure a high reduction effect of power consumption.

Further, according to the first embodiment, the number of branches of the branch signal Sb is represented by ²ⁱ , where i is a natural number, specifically by 2 when i=1. According to this, the number of sets of the differential amplifier 222, the multiplier 23, and the power amplifier 24 corresponds to the number of branches, so that the multiplication after the power distribution and the two-stage amplification sandwiching it are equalized before combining. can be applied to each branch signal Sb. Therefore, in the amplification stage of the power transistors 222a, 222b, 240a, 240b, etc. of each differential amplifier 222 and each power amplifier 24, it is possible to achieve both avoidance of exceeding the withstand voltage limit and reduction of power consumption. becomes.

(Second embodiment)
As shown in FIG. 7, the second embodiment is a modification of the first embodiment.

The power divider 22 of the second embodiment is a transformer branch circuit in which a plurality of differential amplifiers 2222 and transformers 224 are combined with a common transformer distributor 2220 . Also in the second embodiment, the branch number 2i of the branch signal Sb is set to 2, which is the same as the multiplication ratio N (see FIGS. 2 and 3). A pair of differential amplifiers 2222 and transformers 224 are provided according to this setting.

The transformer distributor 2220 is provided with positive and negative input terminals INP and INN. A local signal Sl as a modulated signal amplified by the preamplifier 21 (see FIG. 3) is input to these input terminals INP and INN. Here, also in the second embodiment, the frequency of the local signal Sl is controlled to a value represented by f/2 (that is, a half value of f), for example, 38 GHz, where the multiplication ratio N to the frequency f of the radar wave is 2. ing.

Transformer distributor 2220 is configured by a combination of transformers 2225 and 2226 . Each of the transformers 2225 and 2226 is of a center tap type in which a predetermined gate voltage Vg is applied to the coupling midpoint between each pair of secondary coils 2225b and 2226b.

Each coupling end of each pair of primary coils 2225a in the first transformer 2225 and each coupling end of each pair of primary coils 2226a in the second transformer 2226 are coupled to each other. In the first transformer 2225, the input terminals of the primary coils 2225a are individually connected to the corresponding input terminals INP and INN. The output end of each secondary coil 2225b in the first transformer 2225 is individually connected to the corresponding differential amplifier 2222 in the subsequent stage. The output end of each secondary coil 2226b in the second transformer 2226 is individually connected to the corresponding differential amplifier 2222 in the subsequent stage.

With such a configuration, the transformer distributor 2220 branches the differentially input local signal Sl to the respective differential amplifiers 2222, thereby distributing power to the branched signals Sb to the differential amplifiers 2222. FIG. As a result, a branch signal Sb whose frequency is substantially held at f/2 and whose current is substantially halved (that is, about 1/2) is input to each differential amplifier 2222 .

Each differential amplifier 2222 is provided with a pair of power transistors 2222a and 2222b, which are field effect transistors such as MOSFETs. The gates of the power transistors 2222a and 2222b are individually connected to the output terminals of the corresponding secondary coils 2225b and 2226b of the transformer distributor 2220 in the preceding stage. The sources of power transistors 2222a and 2222b are grounded. The drains of the power transistors 2222a and 2222b are individually connected to the corresponding subsequent transformers 224, respectively. A capacitor 2222c for suppressing oscillation is interposed between the gate of the power transistor 2222a and the drain of the power transistor 2222b and between the gate of the power transistor 2222b and the drain of the power transistor 2222a. Note that the capacitor 2222c may be omitted.

Each transformer 224 is substantially the same as that of the first embodiment except that the input terminals of each pair of primary coils 224a are individually connected to the drains of the corresponding power transistors 2222a and 2222b. Further, each configuration of the multiplier 23, the power amplifier 24, and the power combiner 25 is substantially the same as that of the first embodiment.

From these configurations, each differential amplifier 2222 is supplied with a branch signal Sb power-divided by the transformer distributor 2220 under stable power supply from the corresponding transformer 2224 . Each differential amplifier 2222 amplifies the input branch signal Sb at the frequency f/2 while the parasitic capacitance of the power transistors 2222 a and 2222 b is reduced by the inductor function of the corresponding transformer 224 . The branch signal Sb amplified by each differential amplifier 2222 is input to the corresponding multiplier 23 through the secondary coil 224b of the corresponding transformer 224 .

(Effect)
The effects of the second embodiment described above, which are different from those of the first embodiment, will be described below.

According to the second embodiment, the power divider 22 that power-divides the local signal Sl as the modulating signal into a plurality of branch signals Sb is a transformer branch circuit that is a combination of a transformer divider 2220 and a plurality of differential amplifiers 2222. is. With such a transformer branch circuit, the power loss associated with power distribution between the transformer distributor 2220 and each differential amplifier 2222 can be minimized. Therefore, it is possible to enhance the effect of reducing power consumption.

Also according to the second embodiment, the number of branches of the branch signal Sb is represented by ²ⁱ , where i is a natural number, specifically by 2 when i=1. According to this, the number of groups of the differential amplifier 2222, the multiplier 23, and the power amplifier 24 corresponds to the number of branches, so that the multiplication after the power distribution and the two-stage amplification sandwiching it are equalized before combining. can be applied to each branch signal Sb. Therefore, in the amplification stage of the power transistors 2222a, 2222b, 240a, 240b, etc. of each differential amplifier 2222 and each power amplifier 24, it is possible to achieve both avoidance of exceeding the withstand voltage limit and reduction of power consumption. becomes.

(Other embodiments)

Although a plurality of embodiments have been described above, the present disclosure is not to be construed as being limited to those embodiments, and can be applied to various embodiments and combinations within the scope of the present disclosure. can be done.

Alternate power dividers 22 may be, for example, Wilkinson branch circuits or merchant balun branch circuits. At least one of the modified amplifiers 222 and 2222 and the power amplifier 24 may be, for example, a single-ended amplifier circuit. The modified transformer 224 may be, for example, single-ended. The modified power combiner 25 may be, for example, a transformer combining circuit or a merchant balun combining circuit. The power transistors 220a, 220b, 222a, 222b, 240a, 240b, 2222a, 2222b of the modified examples may be replaced with bipolar transistors such as IGBTs (Insulated Gate Bipolar Transistors). The radar device 1 and the radar circuit unit 4 of the modification may not have some or all of the functions of at least one of the receiver 30 and the controller 10 .

2 transmission antenna, 4 radar circuit unit, 22 power divider, 23 multiplier, 24 power amplifier, 25 power combiner, 220 differential divider, 222, 2222 differential amplifier, 2220 transformer divider, Sl local signal, Ss transmission signal

Claims (5)

A radar circuit unit (4) for generating a transmission signal (Ss) converted and output to a radar wave by a transmission antenna (2) based on a frequency-controlled modulated signal (Sl),
a power divider (22) for power-dividing the modulated signal having a frequency lower than that of the radar wave into a plurality of branch signals;
a plurality of multipliers (23) for individually frequency-multiplying each of the branch signals, the power of which is divided by the power divider, in accordance with the radar wave;
a plurality of power amplifiers (24) for individually amplifying the branched signals frequency-multiplied by each of the multipliers;
a power combiner (25) that combines the branched signals amplified by each of the power amplifiers into the transmission signal;
radar circuit unit. The power divider is
a differential splitter (220) for splitting the modulated signal into each of the split signals;
a plurality of differential amplifiers (222) for amplifying and inputting each of the branched signals branched by the differential divider to the corresponding multiplier;
2. A radar circuit unit according to claim 1, which is a combined cascode branch circuit of . The power divider is
a transformer splitter (2220) for splitting the modulated signal into each of the split signals;
a plurality of differential amplifiers (2222) for amplifying and inputting each of the branched signals branched by the transformer distributor to the corresponding multipliers;
2. A radar circuit unit according to claim 1, which is a combined transformer branch circuit of: 4. The radar circuit unit according to claim 2, wherein the number of branches of said branch signal is represented by ²ⁱ , where i is a natural number. A radar circuit unit according to any one of claims 1 to 4;
the transmitting antenna that converts the transmission signal generated by the radar circuit unit into the radar wave and outputs the radar wave;
A radar device comprising:

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