The present invention relates to a polyphase filter including a transistor.
In a wireless communication device, a semiconductor integrated circuit that processes high-frequency received signals is used in many cases.
For example, in a semiconductor integrated circuit that forms a superheterodyne receiver for a radar, in addition to a filter capable of limiting the frequency band of received signals, there is a case that a polyphase filter or the like capable of suppressing image disturbing waves associated with frequency conversion of received signals is used.
The following Patent Literature 1 discloses a polyphase filter including a plurality of resistors and a plurality of capacitors.
The polyphase filter is originally used for generation of signals with a 90-degree phase difference, and the like, but is also capable of suppressing image disturbing waves.
In the polyphase filter, frequencies at which image disturbing waves can be suppressed change dependently on the resistance values of the resistors included therein and the capacitance values of the capacitors included therein.
A center frequency Fc of the frequencies at which image disturbing waves can be suppressed is represented by the following formula (1):
In formula (1), R represents the resistance values of the resistors and C represents the capacitance values of the capacitors.
Patent Literature 1: JP 2010-21826 A
Since the conventional polyphase filter is formed as described above, by controlling the resistance values R of the resistors included therein, the frequencies at which image disturbing waves can be suppressed can be changed. However, since the polyphase filter is formed using a resistor which is a passive element, there is a problem that pass loss occurs upon suppression of image disturbing waves.
The invention is made to solve the above problem, and an object of the invention is to obtain a polyphase filter capable of suppressing the occurrence of pass loss.
A polyphase filter according to the present invention includes: a first transistor amplifying a first I signal inputted from a first input terminal; a second transistor amplifying a first Q signal inputted from a second input terminal; a third transistor amplifying a second I signal when the second I signal is inputted from a third input terminal, the second I signal forming a differential signal with the first I signal; a fourth transistor amplifying a second Q signal when the second Q signal is inputted from a fourth input terminal, the second Q signal forming a differential signal with the first Q signal; a first capacitor connected between an output terminal of the first transistor and the second input terminal; a second capacitor connected between an output terminal of the second transistor and the third input terminal; a third capacitor connected between an output terminal of the third transistor and the fourth input terminal; and a fourth capacitor connected between an output terminal of the fourth transistor and the first input terminal.
According to the invention, the configuration includes: a first transistor amplifying a first I signal inputted from a first input terminal; a second transistor amplifying a first Q signal inputted from a second input terminal; a third transistor amplifying a second I signal when the second I signal is inputted from a third input terminal, the second I signal forming a differential signal with the first I signal; and a fourth transistor amplifying a second Q signal when the second Q signal is inputted from a fourth input terminal, the second Q signal forming a differential signal with the first Q signal. Thus, there is an effect of being able to suppress the occurrence of pass loss.
For explaining the present invention in more detail, some embodiments for carrying out the invention will be described below with reference to the accompanying drawings.
In
A second input terminal 1b is a terminal to which a first Q signal VQP is inputted.
A third input terminal 1c is a terminal to which a second I signal VIN which forms a differential signal with the first I signal VIP is inputted. Ideally, VIP VIN=0.
A fourth input terminal 1d is a terminal to which a second Q signal VQN which forms a differential signal with the first Q signal VQP is inputted. Ideally, VQP+VQN=0.
A first transistor 2a is a bipolar transistor having a transconductance gm and having an emitter terminal grounded.
The first transistor 2a has a base terminal connected to the first input terminal 1a and a collector terminal (an output terminal of the first transistor 2a) connected to a first output terminal 4a, and amplifies the first I signal VIP inputted from the first input terminal 1a and outputs the amplified first I signal VIP to the first output terminal 4a.
A second transistor 2b is a bipolar transistor having a transconductance gm and having an emitter terminal grounded.
The second transistor 2b has a base terminal connected to the second input terminal 1b and a collector terminal (an output terminal of the second transistor 2b) connected to a second output terminal 4b, and amplifies the first Q signal VQP inputted from the second input terminal 1b and outputs the amplified first Q signal VQP to the second output terminal 4b.
A third transistor 2c is a bipolar transistor having a transconductance gm and having an emitter terminal grounded.
The third transistor 2c has a base terminal connected to the third input terminal 1c and a collector terminal (an output terminal of the third transistor 2c) connected to a third output terminal 4c, and amplifies the second I signal VIN inputted from the third input terminal 1c and outputs the amplified second I signal VIN to the third output terminal 4c.
A fourth transistor 2d is a bipolar transistor having a transconductance gm and having an emitter terminal grounded.
The fourth transistor 2d has a base terminal connected to the fourth input terminal 1d and a collector terminal (an output terminal of the fourth transistor 2d) connected to a fourth output terminal 4d, and amplifies the second Q signal VQN inputted from the fourth input terminal 1d and outputs the amplified second Q signal VQN to the fourth output terminal 4d.
A first capacitor 3a has one end connected to the collector terminal of the first transistor 2a and the other end connected to the second input terminal 1b.
A second capacitor 3b has one end connected to the collector terminal of the second transistor 2b and the other end connected to the third input terminal 1c.
A third capacitor 3c has one end connected to the collector terminal of the third transistor 2c and the other end connected to the fourth input terminal 1d.
A fourth capacitor 3d has one end connected to the collector terminal of the fourth transistor 2d and the other end connected to the first input terminal 1a.
The first output terminal 4a is connected to the collector terminal of the first transistor 2a and outputs a first I signal VO_IP amplified by the first transistor 2a.
The second output terminal 4b is connected to the collector terminal of the second transistor 2b and outputs a first Q signal VO_QP amplified by the second transistor 2b.
The third output terminal 4c is connected to the collector terminal of the third transistor 2c and outputs a second I signal VO_IN amplified by the third transistor 2c.
The fourth output terminal 4d is connected to the collector terminal of the fourth transistor 2d and outputs a second Q signal VO_QN amplified by the fourth transistor 2d.
The polyphase filter of
A load 5a is a resistor whose impedance is Z, and has one end connected to the collector terminal of the first transistor 2a and the other end connected to the power supply Vcc.
A load 5b is a resistor whose impedance is Z, and has one end connected to the collector terminal of the second transistor 2b and the other end connected to the power supply Vcc.
A load 5c is a resistor whose impedance is Z, and has one end connected to the collector terminal of the third transistor 2c and the other end connected to the power supply Vcc.
A load 5d is a resistor whose impedance is Z, and has one end connected to the collector terminal of the fourth transistor 2d and the other end connected to the power supply Vcc.
In the polyphase filter of
A resistor 6a is connected between the first input terminal 1a and the first output terminal 4a.
A resistor 6b is connected between the second input terminal 1b and the second output terminal 4b.
A resistor 6c is connected between the third input terminal 1c and the third output terminal 4c.
A resistor 6d is connected between the fourth input terminal 1d and the fourth output terminal 4d.
Next, operation will be described.
The conventional polyphase filter shown in
First, a differential signal ΔVIOUT related to I signals which is outputted from the conventional polyphase filter will be described. ΔVIOUT is defined by: ΔVIOUT=VO_IP−VO_IN.
For example, a current Ia flowing through the resistor 6a is represented by the following formula (2), and a current Ib flowing through the first capacitor 3a is represented by the following formula (3).
Hence, a first I signal VO_IP outputted from the first output terminal 4a is represented by the following formula (4):
In formulae (2) to (4), R represents the resistance value of the resistor 6a, C represents the capacitance value of the first capacitor 3a, and Z represents the impedance of the load 5a.
When the current Ia represented by formula (2) and the current Ib represented by formula (3) are substituted into formula (4), the first I signal VO_IP outputted from the first output terminal 4a is represented by the following formula (5):
Although here the first I signal VO_IP is described, a second I signal VO_IN can also be obtained in the same manner.
The second I signal VO_IN is represented by the following formula (6):
By formulae (5) and (6), the differential signal ΔVIOUT related to the I signals is obtained. The differential signal ΔVIOUT is represented by the following formula (7):
Next, a differential signal ΔVQOUT related to Q signals which is outputted from the conventional polyphase filter will be described. ΔVQOUT is defined by: ΔVQOUT=VO_QP−VO_QN.
For example, a current If flowing through the resistor 6b is represented by the following formula (8), and a current Ie flowing through the second capacitor 3b is represented by the following formula (9).
Hence, a first Q signal VO_QP outputted from the second output terminal 4b is represented by the following formula (10):
In formulae (8) to (10), R represents the resistance value of the resistor 6b, C represents the capacitance value of the second capacitor 3b, and Z represents the impedance of the load 5b.
By substituting the current If represented by formula (8) and the current Ie represented by formula (9) into formula (10), the first Q signal VO_QP outputted from the second output terminal 4b is represented by the following formula (11):
Although here the first Q signal VO_QP is described, a second Q signal VO_QN can also be obtained in the same manner.
The second Q signal VO_QN is represented by the following formula (12):
By formulae (11) and (12), the differential signal ΔVQOUT related to the Q signals is obtained. The differential signal ΔVQOUT is represented by the following formula (13):
Here, assuming that the input to the polyphase filter is an ideal differential signal (VIP VIN=0), it is assumed that the inputs to the polyphase filter are short-circuited by IQ as shown in the following formula (14). In this situation, the following formulae (15) and (16) hold:
It can be seen from formulae (15) and (16) that the amplitudes of the IQ signals are constant regardless of the frequency, and the phases of the IQ signals represents a 90-degree difference only at an angular frequency ω=1/CR. In addition, since the relation numerator>denominator is held, it can be seen that the IQ signals attenuates.
Next, the polyphase filter of
First, a differential signal ΔVIOUT related to I signals which is outputted from the polyphase filter will be described. ΔVIOUT is defined by: ΔVIOUT=VO_IP−VO_IN.
For example, a current Ia flowing through the first transistor 2a is represented by the following formula (17), and a current Ib flowing through the first capacitor 3a is represented by the following formula (18).
Hence, a first I signal VO_IP outputted from the first output terminal 4a is represented by the following formula (18):
In formula (18), gm is the transconductance of the first transistor 2a.
By substituting the current Ia represented by formula (17) and the current Ib represented by formula (18) into formula (19), the first I signal VO_IP outputted from the first output terminal 4a is represented by the following formula (20):
Although here the first I signal VO_IP is described, a second I signal VO_IN can also be obtained in the same manner.
The second I signal VO_IN is represented by the following formula (21):
By formulae (20) and (21), the differential signal ΔVIOUT related to the I signals is obtained. The differential signal ΔVIOUT is represented by the following formula (22):
Next, a differential signal ΔVQOUT related to Q signals which is outputted from the polyphase filter will be described. ΔVQOUT is defined by: ΔVQOUT=VO_QP−VO_QN.
For example, a current If flowing through the second transistor 2b is represented by the following formula (23), and a current Ie flowing through the second capacitor 3b is represented by the following formula (24).
Hence, a first Q signal VO_QP outputted from the second output terminal 4b is represented by the following formula (25):
By substituting the current If represented by formula (23) and the current Ie represented by formula (24) into formula (25), the first Q signal VO_QP outputted from the second output terminal 4b is represented by the following formula (26):
Although here the first Q signal VO_QP is described, a second Q signal VO_QN can also be obtained in the same manner.
The second Q signal VO_QN is represented by the following formula (27):
By formulae (26) and (27), the differential signal ΔVQOUT related to the Q signals is obtained. The differential signal ΔVQOUT is represented by the following formula (28):
Here, assuming that the input to the polyphase filter is an ideal differential signal (VIP+VIN=0), it is assumed that the inputs to the polyphase filter are short-circuited by IQ as shown in the following formula (29). In this situation, the following formulae (30) and (31) hold:
It can be seen from formulae (30) and (31) that the amplitudes of the IQ signals are always constant, and the phases of the IQ signals represent a 90-degree difference at an angular frequency ω=gm/CR.
The following table 1 shows comparison between the transfer function of the polyphase filter of
The polyphase filter of the first embodiment differs from the polyphase filter of
Hence, also in the polyphase filter of the first embodiment, as with the polyphase filter of
Therefore, the polyphase filter of the first embodiment can implement the same IQ characteristics as the polyphase filter of
However, unlike the polyphase filter of
The gain that the polyphase filter of the first embodiment can have is determined in accordance with the magnitude relationship between the transconductance gm and ωC, as shown in the following table 2. ω is the angular frequency and C is the capacitance value of each of the first capacitor 3a, the second capacitor 3b, the third capacitor 3c, and the fourth capacitor 3d.
When ωC=gm, since the numerator is larger than the denominator, the gain is greater than or equal to 1. In addition, when ωC<<gm, the gain is greater than or equal to 1, too.
Therefore, the polyphase filter of the first embodiment can have a gain greater than or equal to 1 regardless of the magnitude relationship between the transconductance gm and ωC.
In addition, in the polyphase filter of the first embodiment, the angular frequency is determined by ω=gm/CR. Since the transconductance gm is determined by a current flowing through the transistor, the angular frequency ω can be changed by changing the current. Therefore, in the polyphase filter of the first embodiment, it is possible to change the characteristics.
As is clear from the above, according to the first embodiment, the configuration includes: a first transistor 2a amplifying a first I signal VIP inputted from a first input terminal 1a; a second transistor 2b amplifying a first Q signal VQP inputted from a second input terminal 1b; a third transistor 2c amplifying a second I signal VIN when the second I signal VIN is inputted from a third input terminal 1c, the second I signal VIN forming a differential signal with the first I signal VIP; a fourth transistor 2d amplifying a second Q signal VQN when the second Q signal VQN is inputted from a fourth input terminal 1d, the second Q signal VQN forming a differential signal with the first Q signal VQP. Thus, an effect of being able to suppress the occurrence of pass loss is achieved.
In addition, a polyphase filter that has gain and that can change its characteristics can be obtained.
In addition, according to the first embodiment, the collector terminals of the first transistor 2a, the second transistor 2b, the third transistor 2c, and the fourth transistor 2d are connected to the power supply Vcc through the loads 5a, 5b, 5c, and 5d, respectively, and thus, NPN bipolar transistors can be used as the first transistor 2a, the second transistor 2b, the third transistor 2c, and the fourth transistor 2d.
Although the first embodiment shows an example in which the first transistor 2a, the second transistor 2b, the third transistor 2c, and the fourth transistor 2d are bipolar transistors, the transistors are not limited to bipolar transistors and any transistor having the transconductance gm may be used for them.
Hence, the first transistor 2a, the second transistor 2b, the third transistor 2c, and the fourth transistor 2d may be, for example, field-effect transistors or MOS transistors such as complementary metal oxide semiconductor (CMOS) transistors.
Note that when the first transistor 2a, the second transistor 2b, the third transistor 2c, and the fourth transistor 2d are field-effect transistors, the gate terminal of the field-effect transistor corresponds to the base terminal of the bipolar transistor.
In addition, the drain terminal of the field-effect transistor corresponds to the collector terminal of the bipolar transistor, and the source terminal of the field-effect transistor corresponds to the emitter terminal of the bipolar transistor.
The above-described first embodiment shows an example in which the emitter terminal of each of the first transistor 2a, the second transistor 2b, the third transistor 2c, and the fourth transistor 2d are grounded.
In this second embodiment, an example will be described in which the emitter terminal of the first transistor 2a and the emitter terminal of the third transistor 2c are connected to the ground through a first current source 7a, and the emitter terminal of the second transistor 2b and the emitter terminal of the fourth transistor 2d are connected to the ground through a second current source 7b.
The first current source 7a has a + side connected to the emitter terminal of the first transistor 2a and the emitter terminal of the third transistor 2c, and a − side connected to the ground.
The second current source 7b has a + side connected to the emitter terminal of the second transistor 2b and the emitter terminal of the fourth transistor 2d, and a − side connected to the ground.
Although in
Next, operation will be described.
Even when differential imbalance occurs between the first I signal VIP and the second I signal VIN, by connecting the emitter terminal of the first transistor 2a and the emitter terminal of the third transistor 2c to the ground through the first current source 7a, the current Ia flowing through the first transistor 2a and the current Id flowing through the third transistor 2c become a differential signal.
In addition, even when differential imbalance occurs between the first Q signal VQP and the second Q signal VQN, by connecting the emitter terminal of the second transistor 2b and the emitter terminal of the fourth transistor 2d to the ground through the second current source 7b, the current If flowing through the second transistor 2b and the current Ih flowing through the fourth transistor 2d become a differential signal.
By this, the accuracy of suppression of image disturbing waves by the polyphase filter can be increased comparing with the above-described first embodiment.
The second embodiment shows an example in which the emitter terminal of the first transistor 2a and the emitter terminal of the third transistor 2c are connected to the ground through the first current source 7a, and the emitter terminal of the second transistor 2b and the emitter terminal of the fourth transistor 2d are connected to the ground through the second current source 7b.
As shown in
Although the second embodiment shows an example in which the first transistor 2a, the second transistor 2b, the third transistor 2c, and the fourth transistor 2d are bipolar transistors, as in the above-described first embodiment, the transistors may be, for example, field-effect transistors or MOS transistors such as CMOS transistors.
The above-described first embodiment shows an example in which the emitter terminal of each of the first transistor 2a, the second transistor 2b, the third transistor 2c, and the fourth transistor 2d is grounded.
In this third embodiment, an example will be described in which a base terminal of each of a first transistor 9a, a second transistor 9b, a third transistor 9c, and a fourth transistor 9d is grounded.
The first transistor 9a is a bipolar transistor having a transconductance gm and having a base terminal grounded.
The first transistor 9a has an emitter terminal connected to the first input terminal 1a and a collector terminal (an output terminal of the first transistor 9a) connected to the first output terminal 4a, and amplifies a first I signal VIP inputted from the first input terminal 1a and outputs the amplified first I signal VIP to the first output terminal 4a.
The second transistor 9b is a bipolar transistor having a transconductance gm and having a base terminal grounded.
The second transistor 9b has an emitter terminal connected to the second input terminal 1b and a collector terminal (an output terminal of the second transistor 9b) connected to the second output terminal 4b, and amplifies a first Q signal VQP inputted from the second input terminal 1b and outputs the amplified first Q signal VQP to the second output terminal 4b.
The third transistor 9c is a bipolar transistor having a transconductance gm and having a base terminal grounded.
The third transistor 9c has an emitter terminal connected to the third input terminal 1c and a collector terminal (an output terminal of the third transistor 9c) connected to the third output terminal 4c, and amplifies a second I signal VIN inputted from the third input terminal 1c and outputs the amplified second I signal VIN to the third output terminal 4c.
The fourth transistor 9d is a bipolar transistor having a transconductance gm and having a base terminal grounded.
The fourth transistor 9d has an emitter terminal connected to the fourth input terminal 1d and a collector terminal (an output terminal of the fourth transistor 9d) connected to the fourth output terminal 4d, and amplifies a second Q signal VQN inputted from the fourth input terminal 1d and outputs the amplified second Q signal VQN to the fourth output terminal 4d.
A first current source 10a has a + side connected to the emitter terminal of the first transistor 9a and a − side connected to the ground.
A second current source 10b has a + side connected to the emitter terminal of the second transistor 9b and a − side connected to the ground.
A third current source 10c has a + side connected to the emitter terminal of the third transistor 9c and a − side connected to the ground.
A fourth current source 10d has a + side connected to the emitter terminal of the fourth transistor 9d and a − side connected to the ground.
Although in
Next, operation will be described.
The operation of the polyphase filter of the third embodiment is almost the same as that of the polyphase filter of the above-described first embodiment.
However, in the third embodiment, the base terminal of each of the first transistor 9a, the second transistor 9b, the third transistor 9c, and the fourth transistor 9d is grounded.
Hence, the input impedances viewed from the first input terminal 1a, the second input terminal 1b, the third input terminal 1c, and the fourth input terminal 1d can be set to 1/gm of the impedances in the first transistor 9a, the second transistor 9b, the third transistor 9c, and the fourth transistor 9d.
By this, by setting the transconductances gm of the first transistor 9a, the second transistor 9b, the third transistor 9c, and the fourth transistor 9d in accordance with the output impedances viewed from the first output terminal 4a, the second output terminal 4b, the third output terminal 4c, and the fourth output terminal 4d, broadband input and output matching can be implemented. In addition, by eliminating unnecessary matching elements, the size can be reduced, and broadband performance can be enhanced.
In the third embodiment, the emitter terminal of the first transistor 9a is connected to the ground through the first current source 10a, and the emitter terminal of the second transistor 9b is connected to the ground through the second current source 10b. In addition, the emitter terminal of the third transistor 9c is connected to the ground through the third current source 10c, and the emitter terminal of the fourth transistor 9d is connected to the ground through the fourth current source 10d.
As shown in
Although the third embodiment shows an example in which the first transistor 9a, the second transistor 9b, the third transistor 9c, and the fourth transistor 9d are bipolar transistors, the first transistor 9a, the second transistor 9b, the third transistor 9c, and the fourth transistor 9d may be, for example, field-effect transistors or MOS transistors such as CMOS transistors.
Note that in the present invention, a free combination of the embodiments, modifications to any component of the embodiments, or omissions of any component in the embodiments are possible within the scope of the invention.
The invention is suitable for a polyphase filter including a transistor.
1
a: First input terminal, 1b: Second input terminal, 1c: Third input terminal, 1d: Fourth input terminal, 2a: First transistor, 2b: Second transistor, 2c: Third transistor, 2d: Fourth transistor, 3a: First capacitor, 3b: Second capacitor, 3c: Third capacitor, 3d: Fourth capacitor, 4a: First output terminal, 4b: Second output terminal, 4c: Third output terminal, 4d: Fourth output terminal, 5a to 5d: Load, 6a to 6d: Resistor, 7a: First current source, 7b: Second current source, 8a: First resistor, 8b: Second resistor, 9a: First transistor, 9b: Second transistor, 9c: Third transistor, 9d: Fourth transistor, 10a: First current source, 10b: Second current source, 10c: Third current source, 10d: Fourth current source, 11a: First resistor, 11b: Second resistor, 11c: Third resistor, and 11d: Fourth resistor.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2017/008239 | 3/2/2017 | WO | 00 |