JP3776896B2 - Power circuit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power supply circuit for a mobile terminal including a battery protection circuit that operates when a current exceeding a predetermined threshold flows.
[0002]
[Prior art]
Mobile terminals are becoming smaller and lighter. In recent years, there are an increasing number of folding-type terminals that can simultaneously enlarge the button unit and the display unit in order to reduce the size, improve the operational convenience, and improve the display visibility. In addition, since the multi-functionalization is progressing, the demand for the battery current is also increasing, and the threshold for operating the battery protection circuit (for example, see Patent Documents 1 and 2) has to be raised.
[0003]
Referring to FIG. 9, the configuration of a conventional power supply circuit and its peripheral part is shown. A signal to be transmitted (such as sound) is transmitted from the baseband LSI 906 to the quadrature modulator 905 as I and Q signals. The quadrature modulator 905 adds the I and Q signals to the transmission frequency component. This signal is amplified by a driver amplifier 904 and a power amplifier 902, and transmitted from an antenna (not shown) through an isolator 901.
[0004]
In a PDC (Personal Digital Cellular) system that is mainly used in mobile phones in Japan, in general, a transmission amplifier (power amplifier 902) includes a battery voltage power source (output of the battery 907) and a negative voltage for gate bias (output of the battery 907). −2.5V, the output of the negative voltage generator 903). This is because importance is placed on the efficiency (consumption current) of the amplifier. For this reason, the amplification characteristic changes depending on the power supply voltage, and generally the best characteristic is obtained at a high voltage (in a general circuit, a constant voltage output is used in order to avoid a characteristic change due to power supply voltage fluctuation). Further, since the battery voltage is directly used, an FET (power amplifier power control FET 908) functioning as a power ON / OFF switch is disposed between the battery and the battery. The gate of the power amplifier power control FET 908 is connected to the transmission control of the baseband LSI 906.
[0005]
[Patent Document 1]
JP-A-8-149701 [Patent Document 2]
JP-A-2002-176730 [0006]
[Problems to be solved by the invention]
As described above, the power amplifier power control FET 908 of the conventional power circuit is controlled only by the baseband LSI 906. Therefore, when the control line becomes a logic voltage of FET-ON (Hi or Lo, but Lo active when the power amplifier power control FET 908 is a Pch MOSFET) when the control line is other than transmission for some reason (ie, malfunction), The battery 907 and the power amplifier 902 are connected. Since the power amplifier 902 operates when a voltage is applied, it continues to transmit errors until the battery becomes empty. In general, a high-output amplifier generates a large amount of heat, so the power amplifier 902 continues to generate heat during this time (if this actually occurs, if the mounting position of the power amplifier 902 is close to the housing surface, it will be used) Users will feel that their phone is hot when they do n’t.)
[0007]
Certainly, even in the conventional power supply circuit, the battery protection circuit operates for an abnormal current exceeding the threshold value at which the battery protection circuit operates. Therefore, the above problem is solved by the operation of the battery protection circuit. However, when the abnormal current is equal to or less than the threshold value of the battery protection circuit, the battery protection circuit does not operate, and thus it is impossible to prevent useless power consumption. Furthermore, as described above, for the purpose of increasing the functionality of the mobile terminal, if the threshold value at which the battery protection circuit operates is increased, a larger abnormal current is allowed, and this problem becomes more serious.
[0008]
An object of the present invention is to provide a power supply circuit that stops operation even when an abnormal current below a threshold value of a battery protection circuit flows through a power amplifier or the like directly connected to a battery output.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a battery protection circuit that operates when a current exceeding a predetermined threshold value flows. In the power supply circuit of a mobile terminal, the first monitoring the voltage at a predetermined location in the power supply circuit is provided. And the second means for determining the presence or absence of an abnormal current smaller than the threshold value from the monitoring result of the first means and the second means, and the second means, It has 3rd means to operate the said battery protection circuit by sending a big electric current, It is characterized by the above-mentioned. Specifically, the third means is an FET that short-circuits the battery protection circuit when a signal output when the second means determines the presence of an abnormal current is used as a gate signal. .
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described in detail with reference to the drawings.
[0011]
(First embodiment)
Referring to FIG. 1, there is shown a configuration of a power supply circuit and its peripheral part according to a first embodiment of the present invention. Compared with the configuration of the conventional power supply circuit and its peripheral portion shown in FIG. 9 and shown in the related art, a detection circuit 108 and FET2 109b are newly added, and an abnormal current below the threshold value of the battery protection circuit flows. Even in the case of falling into, the battery protection circuit is activated by short-circuiting the battery protection circuit.
[0012]
The detection circuit 108 includes a voltage monitoring unit 108a, a determination unit 108b, a resistor 108c, and a timer 108d. The voltage monitoring unit 108a monitors the negative voltage generation unit 103 and the source and drain voltages of the FET1 109a, and outputs the result to the determination unit 108b. The determination unit 108b determines the state based on the transmission control of the baseband LSI 106 and the input from the voltage monitoring unit 108a. The resistor 108c is a resistor that determines the threshold level of the voltage monitoring unit 108a. The timer 108d gives the determination unit 108b time to activate the battery protection circuit by short-circuiting the battery protection circuit. Since the detection circuit 108 uses the backup power supply of the baseband LSI 106, it can operate even when the output of the battery 107 is OFF.
[0013]
The gate terminal of the FET2 109b is connected to the determination unit 108b, and the protection circuit 107a is short-circuited by a signal from the determination unit 108b.
[0014]
As described above, the monitoring points of the voltage monitoring unit 108a are the source voltage, drain voltage, and output of the negative voltage generation unit 103 of the FET1 109a. The detection circuit 108
(1) In order to prevent heat generation due to erroneous transmission, whether or not it is a transmission timing (whether there is no erroneous transmission),
(2) Since transmission is not performed when a negative voltage is not applied to the power amplifier 102 (abnormal current flows), whether or not a negative voltage is applied to the power amplifier 102 during normal transmission control,
(3) In order to prevent abnormal current from flowing due to failure of the power amplifier 102, whether or not abnormal current flows during normal transmission control,
(4) In order to prevent the abnormal current from flowing due to the failure of the power amplifier power supply control FET 109 (FET1 109a), it is detected whether or not the abnormal current is flowing in the power amplifier power line during non-transmission.
[0015]
First, regarding (1), if the transmission is normal, the transmission control logic of the baseband LSI 106 matches the output of the negative voltage generation unit 103. That is, by determining these ANDs, it is possible to determine whether or not it is a transmission timing. If only the transmission control of the baseband LSI 106 is ON logic, the transmission control of the baseband LSI 106 is malfunctioning for some reason. Therefore, the output voltage of the negative voltage generator 103 is measured.
[0016]
Next, regarding (2), the power amplifier 102 uses a depletion type FET inside. This type of FET is characterized in that the operating current can be changed by a gate bias voltage. Since the parts are designed on the assumption that the output of the negative voltage generator 103 is applied, if the power amplifier 102 is used without the output of the negative voltage generator 103 being applied, an abnormally large current flows. . Since heat is generated when a large current flows through the power amplifier 102, whether or not a negative voltage is applied during normal transmission control is monitored, and if not applied, the transmission is stopped. Therefore, the output voltage of the negative voltage generator 103 is measured.
[0017]
Next, regarding (3), when the power amplifier 102 fails, an abnormally large current may flow. In order to detect this, the source voltage and drain voltage of the FET1 109a are measured, and if the amount of voltage drop is large, it is determined that a large current is flowing. Thus, a measure is taken to stop transmission when the power amplifier fails. Therefore, the source voltage and drain voltage of the FET1 109a are measured.
[0018]
Next, regarding (4), when the FET1 109a fails in a short-circuit state, a power supply voltage is applied to the power amplifier 102. As described above, since the power amplifier 102 operates when a voltage is applied, current flows and heat is generated. In order to prevent this, the drain voltage of the FET1 109a is measured during non-transmission. If the FET1 109a is normal, the drain voltage does not appear (0V). If FET1 109a has a short circuit fault, some voltage is observed at the drain of FET1 109a. If this state is left unattended, a large current continues to flow through the power amplifier 102, resulting in a situation where the apparatus generates heat. Therefore, the drain voltage of FET1 109a is measured.
[0019]
Next, the operation of the power supply circuit of this embodiment will be described in detail with reference to the flowchart of FIG.
[0020]
In step 201, the determination unit 108b monitors a signal from the transmission control of the baseband LSI 106, and determines whether transmission control is present (ON or OFF).
[0021]
When the determination unit 108b determines that there is no transmission control (OFF) in step 201, in step 202, the voltage monitoring unit 108a measures the drain voltage of the FET1 109a and outputs the measurement result to the determination unit 108b.
[0022]
In step 203, the determination unit 108b determines whether or not the measurement result is 0V (YES or NO). If it is determined that the measurement result is 0V (YES), the process returns to the start of the flowchart.
[0023]
If it is determined that the voltage is not 0 V (NO), in step 204, the determination unit 108b turns on the FET2 109b and shorts the output of the battery 107 to the GND level, thereby operating the protection circuit 107a.
[0024]
In step 205, when the determination unit 108b recognizes that T seconds have elapsed by the timer 108d (YES), in step 206, the FET2 109b is turned off and the short circuit state is released.
[0025]
If the determination unit 108 b determines that transmission control is present (ON) in step 201, the voltage monitoring unit 108 a measures the voltage of the negative voltage generation unit 103 in step 207.
[0026]
If the measurement result is abnormal (NG) in step 207, the determination unit 108b turns on the FET2 109b and operates the protection circuit 107a of the battery 107 in step 208.
[0027]
In step 209, when the determination unit 108b recognizes the elapse of T seconds by the timer 108d (YES), in step 210, the FET2 109b is turned off and the short-circuit state is released.
[0028]
If the measurement result is normal (OK) in step 207, in step 211, the voltage monitoring unit 108a measures the potential difference between the source and drain of the FET1 109a.
[0029]
In step 212, if the potential difference is smaller than V _th determined by the resistor 108c (YES), it is determined as normal and the process returns to the start of the flowchart.
[0030]
In step 212, if the potential difference is greater than _Vth determined by the resistor 108c (NO), it is determined that there is an abnormality, and in step 208, the determination unit 108b turns on the FET2 109b and turns on the protection circuit 107a of the battery 107. Make it work.
[0031]
In step 209, when the determination unit 108b recognizes the elapse of T seconds by the timer 108d (YES), in step 210, the FET2 109b is turned off and the short-circuit state is released.
[0032]
Through these series of operations, the protection circuit 107a of the battery 107 can be operated at the time of malfunction regardless of the magnitude of malfunction current.
[0033]
(Second Embodiment)
Referring to FIG. 3, the configuration of the power supply circuit and its peripheral part according to the second embodiment of the present invention is shown. Basically the same as the power supply circuit of the first embodiment, but instead of the power amplifier power supply control FET 309, the FET 308d (in the FET2 109b in FIG. 1) operates the protection circuit 307a of the battery 307 in the detection circuit 308. Corresponding)).
[0034]
Next, the operation of the power supply circuit of this embodiment will be described in detail with reference to the flowchart of FIG.
[0035]
In step 401, the determination unit 308b monitors a signal from the transmission control of the baseband LSI 306 and determines whether transmission control is present (ON or OFF).
[0036]
When the determination unit 308b determines that there is no transmission control (OFF) in step 401, in step 402, the voltage monitoring unit 308a measures the drain voltage of the power amplifier power control FET 309 and outputs the measurement result to the determination unit 308b.
[0037]
In step 403, the determination unit 308b determines whether or not the measurement result is 0V (YES or NO). If it is determined that the measurement result is 0V (YES), the process returns to the start of the flowchart.
[0038]
If it is determined that the voltage is not 0V (NO), in step 404, the determination unit 308b turns on the FET 308d and shorts the output of the battery 307 to the GND level, thereby operating the protection circuit 307a.
[0039]
In step 405, when the determination unit 308b recognizes that T seconds have elapsed by the timer 308e (YES), in step 406, the FET 308d is turned off and the short circuit state is released.
[0040]
If the determination unit 308b determines that transmission control is present (ON) in step 401, the voltage monitoring unit 308a measures the voltage of the negative voltage generation unit 303 in step 407.
[0041]
If the measurement result is abnormal (NG) in step 407, in step 408, the determination unit 308b turns on the FET 308d and operates the protection circuit 307a of the battery 307.
[0042]
In step 409, when the determination unit 308b recognizes that T seconds have elapsed by the timer 308e (YES), in step 410, the FET 308d is turned off and the short circuit state is released.
[0043]
If the measurement result is normal (OK) in step 407, the voltage monitoring unit 308a measures the potential difference between the source and drain of the power amplifier power control FET 309 in step 411.
[0044]
If the potential difference is smaller than V _th determined by the resistor 308c (YES) at step 412, it is determined that the voltage is normal and the process returns to the start of the flowchart.
[0045]
If the potential difference is greater than V _th determined by the resistor 308c (NO) at step 412, it is determined that there is an abnormality, and at step 408, the determination unit 308b turns on the FET 308d and operates the protection circuit 307a of the battery 307. Let
[0046]
In step 409, when the determination unit 308b recognizes that T seconds have elapsed by the timer 308e (YES), in step 410, the FET 308d is turned off and the short circuit state is released.
[0047]
Through these series of operations, the protection circuit 307a of the battery 307 can be operated at the time of malfunction regardless of the magnitude of malfunction current.
[0048]
(Third embodiment)
Referring to FIG. 5, the configuration of a power supply circuit and its peripheral part according to a third embodiment of the present invention is shown. Basically, it is the same as the power supply circuit of the first and second embodiments, but the detection circuit 508 has an FET 508d (corresponding to FET2 109b in FIG. 1) for operating the protection circuit 507a of the battery 507, and a power supply for the power amplifier 502. The power amplifier power supply control FET 508e (corresponding to the FET1 109a in FIG. 1) for controlling is taken in.
[0049]
Next, the operation of the power supply circuit of this embodiment will be described in detail with reference to the flowchart of FIG.
[0050]
In step 601, the determination unit 508b monitors a signal from the transmission control of the baseband LSI 506, and determines whether transmission control is present (ON or OFF).
[0051]
If the determination unit 508b determines that there is no transmission control (OFF) in step 601, in step 602, the voltage monitoring unit 508a measures the drain voltage of the power amplifier power control FET 508e and outputs the measurement result to the determination unit 508b.
[0052]
In step 605, the determination unit 508b determines whether or not the measurement result is 0V (YES or NO). If it is determined that the measurement result is 0V (YES), the process returns to the start of the flowchart.
[0053]
If it is determined that the voltage is not 0V (NO), in step 606, the determination unit 508b turns on the FET 508d and shorts the output of the battery 507 to the GND level, thereby operating the protection circuit 507a.
[0054]
In step 605, when the determination unit 508b recognizes the elapse of T seconds by the timer 508f (YES), in step 606, the FET 508d is turned off and the short-circuit state is released.
[0055]
If the determination unit 508b determines that there is transmission control (ON) in step 601, the voltage monitoring unit 508a measures the voltage of the negative voltage generation unit 503 in step 607.
[0056]
If the measurement result is abnormal (NG) in step 607, in step 608, the determination unit 508b turns on the FET 508d and operates the protection circuit 507a of the battery 507.
[0057]
In step 609, when the determination unit 508b recognizes the elapse of T seconds by the timer 508f (YES), in step 610, the FET 508d is turned off and the short-circuit state is released.
[0058]
If the measurement result is normal (OK) in step 607, in step 611, the voltage monitoring unit 508a measures the potential difference between the source and drain of the power amplifier power supply control FET 508e.
[0059]
In step 612, when the potential difference is smaller than V _th determined by the resistor 508c (YES), it is determined as normal and the process returns to the start of the flowchart.
[0060]
In step 612, if the potential difference is larger than _Vth determined by the resistor 508c (NO), it is determined that there is an abnormality, and in step 608, the determination unit 508b turns on the FET 508d and operates the protection circuit 507a of the battery 507. Let
[0061]
In step 609, when the determination unit 508b recognizes the elapse of T seconds by the timer 508f (YES), in step 610, the FET 508d is turned off and the short-circuit state is released.
[0062]
Through these series of operations, the protection circuit 507a of the battery 507 can be operated at the time of malfunction regardless of the magnitude of malfunction current.
[0063]
(Fourth embodiment)
Referring to FIG. 7, there is shown a configuration of a power supply circuit and its peripheral part according to a fourth embodiment of the present invention. The power supply circuit of the fourth embodiment has a configuration in which the abnormality detection at the time of transmission, which is determined twice by the power supply circuits of the first to third embodiments, is made one. That is, the voltage monitoring unit 708a does not measure the voltage of the negative voltage generation unit 703. The power supply circuit of the fourth embodiment will be described as a power supply circuit based on the power supply circuit of the second embodiment for convenience, but any power supply circuit of the first to third embodiments may be used as a base.
[0064]
Next, the operation of the power supply circuit of this embodiment will be described in detail with reference to the flowchart of FIG.
[0065]
In step 801, the determination unit 708b monitors a signal from the transmission control of the baseband LSI 706 to determine whether transmission control is present (ON or OFF).
[0066]
If the determination unit 708b determines that there is no transmission control (OFF) in step 801, in step 802, the voltage monitoring unit 708a measures the drain voltage of the power amplifier power control FET 709 and outputs the measurement result to the determination unit 708b.
[0067]
In step 803, the determination unit 708b determines whether or not the measurement result is 0V (YES or NO). If it is determined that the measurement result is 0V (YES), the process returns to the start of the flowchart.
[0068]
If it is determined that the voltage is not 0V (NO), in step 804, the determination unit 708b turns on the FET 708d and shorts the output of the battery 707 to the GND level, thereby operating the protection circuit 707a.
[0069]
In step 805, when the determination unit 708b recognizes the elapse of T seconds by the timer 708e (YES), in step 806, the FET 708d is turned off and the short-circuit state is released.
[0070]
If the determination unit 708b determines that transmission control is present (ON) in step 801, the voltage monitoring unit 708a measures the potential difference between the source and drain of the power amplifier power control FET 709 in step 807.
[0071]
In step 808, if the potential difference is smaller than V _th determined by the resistor 708c (YES), it is determined as normal and the process returns to the start of the flowchart.
[0072]
In step 808, if the potential difference is larger than _Vth determined by the resistor 708c (NO), it is determined that there is an abnormality, and in step 809, the determination unit 708b turns on the FET 708d and operates the protection circuit 707a of the battery 707. Let
[0073]
In step 810, when the determination unit 708b recognizes the elapse of T seconds by the timer 708e (YES), in step 811, the FET 708d is turned off and the short-circuit state is released.
[0074]
Through these series of operations, the protection circuit 707a of the battery 707 can be operated at the time of malfunction regardless of the magnitude of malfunction current.
[0075]
【The invention's effect】
As described above, according to the present invention, when the threshold current of the battery protection circuit is set high so as to correspond to a large current for reasons such as illumination and sound notification, the protection region and potential of the battery protection circuit Even if a difference occurs from the maximum current of the specific circuit block being monitored, the area where the battery protection circuit does not operate can be eliminated by a minimum circuit change.
[0076]
That is, even when a specific circuit connected directly to the battery output fails or operates abnormally, and an abnormal current that is less than the operating current of the battery protection circuit continues to flow, the battery protection circuit is operated by short-circuiting the battery output. The function of the mobile terminal can be stopped reliably, and the safety of the device is maintained.
[0077]
In this way, with a simple configuration, a fail-safe function can be added that corresponds to a case where a circuit block directly connected to the battery output falls into a failure or abnormal state.
[0078]
In addition, the threshold value of the battery protection circuit can be increased in order to support multiple functions while maintaining the safety of the device.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a power supply circuit and its peripheral part according to a first embodiment of the present invention.
FIG. 2 is a diagram showing an operation of the power supply circuit according to the first embodiment of the present invention.
FIG. 3 is a diagram showing a configuration of a power supply circuit and its peripheral part according to a second embodiment of the present invention.
FIG. 4 is a diagram showing an operation of a power supply circuit according to a second embodiment of the present invention.
FIG. 5 is a diagram showing a configuration of a power supply circuit and its peripheral part according to a third embodiment of the present invention.
FIG. 6 is a diagram showing an operation of a power supply circuit according to a third embodiment of the present invention.
FIG. 7 is a diagram showing a configuration of a power supply circuit and its peripheral part according to a fourth embodiment of the present invention.
FIG. 8 is a diagram showing an operation of a power supply circuit according to a fourth embodiment of the present invention.
FIG. 9 is a diagram showing a configuration of a conventional power supply circuit and its peripheral part.
[Explanation of symbols]
101, 301, 501, 701, 901 Isolators 102, 302, 502, 702, 902 Power amplifiers 103, 303, 503, 703, 903 Negative voltage generators 104, 304, 504, 704, 904 Driver amplifiers 105, 305, 505 , 705, 905 Quadrature modulator 106, 306, 506, 706, 906 Baseband LSI
107, 307, 507, 707, 907 Battery 107a, 307a, 507a, 707a, 907a Protection circuit 107b, 307b, 507b, 707b, 907b Battery cell 108, 308, 508, 708 Detection circuit 108a, 308a, 508a, 708a Voltage monitoring Unit 108b, 308b, 508b, 708b determination unit 108c, 308c, 508c, 708c resistor 108d, 308e, 508f, 708e timer unit 308d, 508d, 708d FET
508e Power amplifier power control FET
109, 309, 709, 908 Power amplifier power control FET
109a FET1
109b FET2
201-212 Step 401-412 Step 601-612 Step 801-811 Step

Claims (7)

In a power supply circuit of a mobile terminal comprising a battery protection circuit that operates when a current exceeding a predetermined threshold flows,
First means for monitoring the voltage at a predetermined location in the power supply circuit;
Second means for determining the presence / absence of an abnormal current smaller than the threshold from the monitoring result of the first means;
When the second means determines that the abnormal current is present, the power supply circuit includes third means for operating the battery protection circuit by flowing a current larger than the threshold value. . The said predetermined | prescribed location is inserted between the transmission amplifier of the said portable terminal, and a battery, The drain terminal and / or source terminal of FET which function as a power ON / OFF switch of the said transmission amplifier are included. Power supply circuit. The power supply circuit according to claim 2, wherein the predetermined portion further includes an output terminal of a negative voltage generation unit that applies a gate bias to the transmission amplifier. The second means determines whether transmission control of the baseband LSI of the portable terminal is ON or OFF, and determines the presence or absence of the abnormal current from the voltage of the drain terminal when it is determined to be OFF. The power supply circuit according to 2. The second means determines whether the transmission control of the baseband LSI of the portable terminal is ON or OFF, and if it is determined to be ON, determines whether the abnormal current exists based on a potential difference between the drain terminal and the source terminal. The power supply circuit according to claim 2. The second means determines whether the transmission control of the baseband LSI of the portable terminal is ON or OFF, and if it is determined to be ON, the presence / absence of the abnormal current is determined from the voltage at the output terminal of the negative voltage generating means. 4. The power supply circuit according to claim 3, wherein, when it is determined that the abnormal current does not exist, the presence or absence of the abnormal current is determined from a potential difference between the drain terminal and the source terminal. The third means is an FET that short-circuits the battery protection circuit when a signal output when the second means determines the presence of the abnormal current is used as a gate signal. The power supply circuit according to any one of claims 1 to 6.

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