DE102010027263A1 - Voltage regulator assembly for smart card, has control transistor with control terminal, where control terminal is connected with output of charge pump - Google Patents

Abstract

The voltage regulator assembly (100) has a control transistor (TR) with a control terminal (G), where the control terminal is connected with an output of a charge pump (10). An oscillator (30) is provided for driving the charge pump by a clock signal with a frequency. A limiting circuit (20) for limiting the frequency of the clock signal of the oscillator is arranged between the oscillator and the charge pump. An independent claim is also included for a method for controlling a voltage in voltage regulator assembly.

Description

The invention relates to a voltage regulator arrangement with a voltage regulator, which is connectable to a circuit arrangement and is provided for supplying the same.

In integrated circuit arrangements, a distinction is made between the internal supply voltage and the external supply voltage. A voltage regulator converts the external supply voltage into an internal supply voltage. The voltage regulator assumes the task of regulating the internal supply voltage to a predetermined value, regardless of the current power consumption. He draws the necessary power from the external supply voltage. In this case, the input terminal of the voltage regulator is supplied with the external supply voltage. At the output of the voltage regulator, which is connectable to the circuit arrangement, then the internal supply voltage is applied. The amount of the internal supply voltage is measured according to the requirements of the circuit arrangement. Usually, the internal supply voltage is lower than the external supply voltage. The internal supply voltage must be kept as constant as possible, regardless of voltage fluctuations of the external supply voltage in order to ensure the function of the circuit arrangement to be supplied.

With increasing technology integration of the components of the circuit arrangement to be supplied, the internal supply voltage usually decreases. At the same time as the permissible external voltage range is extended due to given standards (eg Global System for Mobile Communication GSM or International Standard Organization ISO) and the internal support capacity is reduced due to the reduced area, the requirements for the voltage regulator are tightened to a constant provide internal supply voltage.

In principle, two different types of voltage regulators are known from the prior art.

On the one hand, there are integrated voltage regulators with p-channel linear control transistors which have a low current consumption but a high voltage sensitivity. The high voltage sensitivity is caused by the fact that the external supply voltage is connected to the source terminal of the p-channel longitudinal control transistor. Changes in the external supply voltage have a direct effect on the gate-source voltage and thus significantly change the operating point of the transistor. P-channel long-channel transistors are currently used in integrated circuit voltage regulators for use in smart cards.

Furthermore, voltage regulators with n-channel longitudinal control transistors are known. These have a low voltage sensitivity, since the external supply voltage is connected to the drain terminal of the n-channel longitudinal control transistor. To open the transistor, a gate voltage of at least internal supply voltage plus threshold voltage of the transistor is necessary. In general, this gate voltage necessary to open the transistor is higher than the external supply voltage, so that the use of a charge pump and a controlled oscillator are required. A disadvantage of this type, however, is the increased power consumption, which are necessary by the oscillator and the charge pump. As a result, voltage regulators with an n-channel longitudinal control transistor have an increased power consumption. This often leads to a considerable effort to comply with the above-mentioned GSM or ISO standards.

The problem is the use of n-channel voltage regulators, for example, for use in smart cards, in which a maximum power consumption may not be exceeded in certain operating situations.

Examples of known voltage regulators are known from EP 1490742 known.

The object of the present invention is to provide a voltage regulator arrangement with improved regulator characteristics.

This object is achieved with a voltage regulator arrangement having the features of claim 1 and with a method for regulating a voltage in a voltage regulator arrangement. Advantageous embodiments of the voltage regulator arrangement and of the method for regulating a voltage in a voltage regulator arrangement result from the dependent claims.

The voltage regulator arrangement has a control transistor, which is operated as a voltage follower, with a control terminal. The control terminal is connected to a charge pump, which is controlled by an oscillator by a clock signal with a changing frequency. The limitation of the power consumption is effected by limiting the frequency of the clock signal of the oscillator by means of a limiting circuit which is arranged between the oscillator and the charge pump.

The magnitude of the current of the voltage regulator arrangement depends on the frequency of the clock signal of the oscillator, with which the charge pump is driven. By limiting the frequency of the clock signal by the limiting circuit ensures that the current does not rise too high and thereby moves within the known standards. The clock and thus current limit is performed for example when switching the voltage regulator assembly.

A charge pump is understood to mean a means for generating a voltage above the supply voltage. For some control transistors, for example n-channel control transistor, for example, a voltage which is increased at the control connection in relation to a source connection is necessary. This is provided by the charge pump.

The charge pump may consist of a cascaded arrangement of capacitors and diodes. Due to the oscillating signal of the oscillator, the capacitors of the charge pump are charged with each clock further, so that, at the control terminal of the control transistor, the necessary high voltage can be provided.

In some applications, it is advantageous if the limiting circuit limits the frequency of the clock signal of the oscillator to the external clock frequency. By limiting the frequency of the clock signal to the external clock frequency, it is ensured that the current is limited as a function of the external frequency and thus frequency-dependent specifications in time and current can be met equally without requiring a reference frequency.

In a further embodiment, the control transistor is an n-channel control transistor and / or a MOS control transistor.

• – Erzeugen eines erstes Taktsignals derart, dass die Frequenz des ersten Taktsignals durch eine Frequenz eines zweites Taktsignal begrenzt wird,
• – Ansteuerung einer Ladungspumpe durch das erste Taktsignal,
• – Steuern eines Steueranschlusses eines Regeltransistors mittels eines Ausgangssignals der Ladungspumpe.

The method for controlling a voltage in a voltage regulator arrangement comprises the following steps:

• Generating a first clock signal such that the frequency of the first clock signal is limited by a frequency of a second clock signal,
• Driving a charge pump by the first clock signal,
• - Controlling a control terminal of a control transistor by means of an output signal of the charge pump.

In one embodiment of the method for controlling a voltage in a voltage regulator arrangement, the frequency of the first clock signal is limited to the level of the frequency of the second clock signal, wherein the second clock signal can generally also be supplied externally.

Hereinafter, preferred embodiments of a voltage regulator arrangement will be explained in more detail with reference to FIGS. Show it:

1 an embodiment of a voltage regulator assembly 100 ,

2 Another embodiment of a voltage regulator assembly 100 ,

3 an embodiment of a limiting circuit 20 ,

1 shows an embodiment of a voltage regulator arrangement 100 , The voltage regulator arrangement 100 has a control transistor TR with a control terminal G, wherein the control terminal G to the output of a charge pump 10 connected is. Furthermore, the voltage regulator arrangement 100 a limiting circuit 20 and an oscillator 30 on, where the limiting circuit 20 between the oscillator 30 and the charge pump 10 is arranged. The limitation of the controlled frequency of the oscillator 30 is done by the limiting circuit 20 , The oscillator 30 is through a rule element 50 driven.

The in the 1 illustrated voltage regulator assembly 100 shows at low control deflection in the control behavior no differences compared to an unlimited control behavior, ie a control behavior without the limiting circuit 20 , Only during a high deflection, as is achieved for example during startup, the maximum at the charge pump 10 applied frequency limited to the external clock frequency (exT). The limitation occurs, for example, during the waking up of the voltage regulator arrangement 100 from sleep mode.

2 shows a further embodiment of a voltage regulator arrangement 100 , The voltage regulator arrangement 100 in 2 shows in addition to the voltage regulator assembly 100 in the 1 an embodiment of a control loop. The internal supply voltage Uint is connected via a voltage divider ST to an input of a control amplifier 40 fed back and compared there with the reference voltage Uref. The control of the oscillator 30 is proportional to the voltage difference at the input of the control amplifier 40 , In the embodiment of 2 becomes the frequency of the charge pump 10 limited to the external clock frequency (exT). The limitation of the controlled frequency of the oscillator 30 is done by the limiting circuit 20 , The limitation is the Buffer capacity C loaded slower and the charging current of the buffer capacity C reduced.

3 shows an embodiment of a limiting circuit 20 , The limiting circuit 20 has a clock cell 22 and a register 24 on, where an output Q of the register 24 with the enable input EN of the clock cell 22 connected is. With a rising edge of the external clock frequency exT, a signal is present at the enable input EN of the clock cell 22 on, since the date signal D of the register 24 is preset to the value "1". This allows the following edge of the oscillator clock osc_clk, the clock cell 22 to happen. At the output CPEN of the clock cell 22 This creates a clock edge pump_clk for the charge pump 10 , By this clock edge is also the register 24 reset. Only with the next edge of the external clock frequency exT is there again a signal at the enable input EN of the clock cell 22 so that only then the next edge of the oscillator clock osc_clk the clock cell 22 can happen.

Through this limiting circuit 20 the clock frequency pump_clk at the output CPEN of the clock cell 22 essentially limited to the external clock frequency exT. The possible in this arrangement artifacts in the clock signal due to the unclean synchronization play no role in the present application.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1490742 [0008]

Claims (8)

Voltage regulator arrangement ( 100 ), - a control transistor (TR) with a control terminal (G), wherein the control terminal (G) with an output of a charge pump ( 10 ), - an oscillator ( 30 ) for driving the charge pump ( 10 ) by a clock signal having a frequency, characterized in that between the oscillator ( 30 ) and the charge pump ( 10 ) a limiting circuit ( 20 ) for limiting the frequency of the clock signal of the oscillator ( 30 ) is arranged. Voltage regulator arrangement ( 100 ) according to claim 1, wherein the limiting circuit ( 20 ) is set to the frequency of the clock signal of the oscillator ( 30 ) to the external clock frequency (exT). Voltage regulator arrangement ( 100 ) according to one of the preceding claims, wherein the control transistor (TR) is an n-channel control transistor. Voltage regulator arrangement ( 100 ) according to one of the preceding claims, wherein the control transistor is a MOS control transistor. Chip card, comprising a voltage regulator arrangement ( 100 ) according to any one of the preceding claims. Method for regulating a voltage in a voltage regulator arrangement ( 100 ) comprising the steps: - generating a first clock signal such that the frequency of the first clock signal is limited by a frequency of a second clock signal (exT), - driving a charge pump ( 10 ) by the first clock signal, - control of a control terminal (G) of a control transistor (TR) by means of an output signal of the charge pump ( 10 ). A method of controlling a voltage according to claim 6, wherein the frequency of the first clock signal is limited to the level of the frequency of the second clock signal (exT). A voltage regulating method according to any one of claims 6 or 7, wherein the second clock signal (exT) is externally supplied.

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