WO1998035431A1

WO1998035431A1 - Circuit and method for generating a voltage

Info

Publication number: WO1998035431A1
Application number: PCT/SE1998/000081
Authority: WO
Inventors: Per-Olof Magnus Brandt
Original assignee: Telefonaktiebolaget Lm Ericsson (Publ)
Priority date: 1997-02-05
Filing date: 1998-01-20
Publication date: 1998-08-13
Also published as: SE9700400L; HK1025191A1; AU6008798A; SE9700400D0; BR9807161A; CN1246984A; US5926013A; EE9900298A; CN1118923C; SE511382C2; MY116705A; EP0960470A1

Abstract

The invention relates to a circuit for generating an output voltage (Vout), which is used during active time periods and which is not used during inactive time periods. A DC/DC-converter (T1, D1) converts an input voltage (Vsupply) to the output voltage (Vout). During the inactive time periods a condenser (C1) is charged up with a quantity of charge which is then used in order to generate the output voltage (Vout) during the active time periods. The quantity of charge is generated by a current from a current generator (I). The current is lead to earth via the condenser and a diode (D1). The condenser (C1) is charged up more and more and the current diminishes towards zero. A control voltage (Vctrl) switches the circuit during the active time periods so that the output voltage (Vout) is obtained. The circuit can be used in a radio transmitter comprised in a portable radio equipment, where the radio equipment is used in a radio system where transmissions occur in bursts.

Description

CIRCUIT AND METHOD FOR GENERATING A VOLTAGE

TECHNICAL FIELD

The present invention relates to a circuit and a method for generating a voltage. The voltage is used during active time periods and is not used during inactive time periods.

The invention also relates to the use of the circuit in a radio transmitter comprised in a portable radio equipment.

STATE OF THE ART

In certain applications it is necessary to be able to generate a voltage with special characteristics. One such application can be when the voltage is only required during certain periods of time. The time when the voltage is required can be called an active time period and the time when the voltage is not required can be called an inactive time period.

An example can be when the voltage is generated in order to be used as e.g. the supply voltage to a circuit which is not driven continuously. The supply voltage should be supplied to the circuit during the active time periods and during the inactive time periods not be supplied to the circuit.

An example which can be mentioned is a radio transmitter comprised in a portable radio equipment where the radio equipment is used in a radio system where transmissions occur in bursts. A negative supply voltage to the power amplifier of the radio transmitter is required in this case during every burst transmission. The expression portable radio equipment comprises all portable equipment which is arranged for radio communication, such as for example mobile telephones, pagers, telefax and printer devices and communicators, i.e. telephones with computers and built-in calendars. Said equipment can be used in some type of radio network such as for example cellular networks, satellite networks or smaller local networks.

It is known to use a so called charge-pump in order to produce voltages with the above described features.

An example of this is described in a patent application GB 2, 023, 949. In the said application a negative supply voltage is produced by a circuit which comprises an operational amplifier, a buffer amplifier and a diode pump amplifier. The operational amplifier controls the buffer amplifier so that it is alternately "on" and "off which results in that a charge is pumped into a condenser in the diode pump amplifier and that a negative voltage is obtained.

A disadvantage with the construction according to the said prior art is the use of the operational amplifier and the diode pump amplifier, because the oscillator frequency of the operational amplifier can lie like a ripple on the voltage produced. In order to avoid said ripple extra components are required, e.g. a filter, and despite this it can be difficult to keep the ripple sufficiently low which is well known to the person skilled in the art.

When an oscillator is used the problem of how to obtain a quick and well defined start-up time is also present. Yet another disadvantage in the construction according to the prior art is that the voltage is produced continuously, i.e. even when it is not required, as the charge is supplied to the condenser all the time.

DISCLOSURE OF THE INVENTION

The present invention tackles the problem of how an voltage alternatingly can be produced in a simple manner.

Another problem is how the voltage can be produced without a ripple arising on the voltage produced.

Yet another problem is how quick and well-defined transit times can be obtained.

Yet another problem is how the voltage can be produced only during the time periods when it is required.

An object with the present invention is consequently to tackle the above problems.

Yet another object is to provide a simple and cheap circuit for producing the voltage.

A solution according to the invention is to charge up a condenser during the time when the voltage is not required. When the voltage is required the condenser is discharged whereby a voltage is obtained.

The solution comprises a control voltage and an input voltage connected to the circuit. The control voltage switches the circuit between active and inactive time periods. A DC/DC-converter converts the input voltage to the desired output voltage during the active time periods. The output voltage is produced by means of a quantity of charge which is stored in a storage means whereby the storage means is charged up with the quantity of charge during the inactive time periods. The quantity of charge is generated by a current which is produced by a current generator.

The present invention has several advantages. A voltage can alternatingly be produced in a simple manner wherein the voltage can be produced without ripples arising on the voltage produced.

Another advantage is that quick and well defined transit times are obtained and that the voltage is produced only during the time periods when it is required to be used.

Yet another advantage is that a simple and cheap circuit for the production of the voltage is obtained with the invention.

The invention will now be described more closely with the help of preferred embodiments and with reference to the accompanying drawings.

DESCRIPTION OF THE FIGURES

Figure la shows a circuit for the production of a voltage and illustrates the principle according to the invention.

Figure lb shows an embodiment of the circuit according to the invention.

Figure lc shows another embodiment of the circuit according to the invention.

Figure 2 shows a further embodiment of a circuit according to the invention. Figure 3 shows the control voltage and the output voltage from the circuit according to the invention as a function of time.

Figure 4 shows a schematic flow diagram of a method for the production of a voltage according to the invention.

PREFERRED EMBODIMENTS

In Figure la a circuit for generating a voltage is shown. The circuit is schematic and illustrates the principle for the invention. A current generator I is connected in series with a parallel connection comprising a first branch which comprises a condenser Cl in series with a diode Dl and a second branch which comprises a transistor Tl, wherein the condenser Cl and the diode Dl are connected in parallel with the transistor T 1.

A supply voltage V_supply is supplied to the circuit via an input IN. A control voltage V_ctrl is supplied to the transistor Tl via a control input CTRL. The control voltage can be characterised by a certain frequency and a certain duty cycle. The duty cycle can e.g. be 1 :8.

An output voltage V_out is obtained at an output OUT as will be explained below. The output voltage is used during the active time periods and not used during the inactive time periods.

Assume first that the circuit is in an inactive time period. According to the invention the control voltage V_ctrl is then low whereby the transistor Tl is cut off. A current will be generated by the current generator I in order to be subsequently lead to earth through the condenser Cl and the diode Dl. The condenser will be charged up more and more during which the current successively diminishes to zero when the condenser is fully charged.

In this way the condenser will function as a storage means for the quantity of charge which is built up in the condenser.

Assume now that the inactive time period changes to an active time period. When this takes place the condenser C 1 is fully charged. The transition or the switching over between the inactive and active time periods is determined by the control voltage V_ctrl. During switching over a high control voltage V_ctrl is applied via the control input CTRL. In this way the transistor Tl will become fully conducting and the potential at the point 1 in the current generator I and the condenser C 1 will be 0 V. At the same time the potential at point 2 will go from x V (the voltage drop over the diode Dl) to -(V_suppι_y - x) V, wherein the output voltage V_out will also have the value -( V_supply - x) V.

The value of x is dependent on which type of diode is used. For example the value can be 0,3 V for a Schottky diode or 0,7 V for a PN-diode. In the following description it is assumed that the diode is a PN-diode, wherein x is approximately equal to 0,7 V.

During the active time period the condenser Cl will be successively emptied of the quantity of charge which is supplied during the inactive time period. The charge is lead to earth through the transistor Tl and V_out takes the value -( ^_supply - x) V as explained above.

When the active time period is over the control voltage V_ctrl again takes a low value whereby the transistor Tl is cut off and the condenser begins to charge up again. When the control voltage is low it is the current generator I which supplies the current which is required in order to charge the condenser C 1.

The current generator I in Figure la can be produced in different ways. One way is to connect a resistor RI between the input IN and the point 1 as shown in Figure lb. Generally it can then be said that the supply voltage V_suppι_y which is supplied to the input IN and the resistor RI form the current generator I in Figure la. The charge time is determined by the RC-constant of the resistor RI and the condenser Cl.

Another way of producing the current generator I is shown in Figure lc. A MESFET-transistor T2 is connected between the input IN and the point 1. The drain connection of the transistor T2 is connected to the input IN, the source connection is connected to the point 1 and the gate connection is connected together with the source connection. In this way a saturated current I_d)Sat is obtained which can be used for charging the condenser Cl as explained above.

The MESFET-transistor T2 limits the current during the active time periods. During the inactive time periods when the condenser is nearly fully loaded the transistor T2 functions as a low resistance.

If the output voltage from the circuit according to the invention is used as the supply voltage to, for example, a power amplifier, which is manufactured by an MESFET-process, a simple solution is obtained with the help of the MESFET- transistor T2. The MESFET-transistor T2 can in this case be integrated in the same manufacturing process as the power amplifier and placed on the same chip as the power amplifier. The diode Dl can also be manufactured in an MESFET- process and integrated on the same chip as the power amplifier and the transistor. Figure 2 shows another embodiment of the invention. The current generator I, which is shown generally in Figure 1 a, comprises in this embodiment the resistors RI, R2, R3 and R4, the condenser C2 and the transistor T3. The transistor T3 is used in order to produce a on/off function of the current generator.

During the inactive time periods the transistor T3 is fully conducting and the current generator consequently supplies current in order to charge up the condenser Cl . During the active time periods the transistor T3 is cut off whereby no current is supplied. The resistors R3 and R4 are used in order to obtain the desired value of the gate current to transistor T3. With the help of the condenser C2 it is ensured that the transistor T3 switches on and off with the help of the control voltage V_ctrl. The resistor R2 functions as a safety resistance in order to limit the current which can pass through the transistor T3.

The DC/DC-converter which is shown generally in Figures la-lc comprises in this embodiment also the resistor R5 and the Zener diode Zl .

The resistor R5 can be used in order to provide a possibility of varying the bass voltage on the transistor T 1.

The diode Zl can be used to avoid variations in the output voltage V_out when the output OUT is loaded with a load, e.g. a power amplifier. According to the invention the Zener diode is to be connected between the control input of the transistor Tl and point 2 as is shown in the Figure, whereby it stabilises voltages less than the Zener voltage minus the voltage drop across the diode Dl. If for example the Zener voltage is 4,8 V and the diode voltage 0,7 V, then the output voltage can never be less than -4,1 V. In this way a voltage stabilising function is obtained in the circuit according to the invention. The transistor Tl and the diode Dl can generally be said to form a DC/DC- converter which it is possible to switch between two states, an active state and an inactive state and the condenser C 1 can generally be said to be a storage means, in which a quantity of charge is stored in order to be used for generating an output voltage V_out during the active time periods.

When the switching takes place between the active and the inactive time periods a changing of the polarity at point 2 occurs. During the inactive time periods the polarity is positive at point 2 but during the active time periods the polarity is negative. For this reason the output voltage V_out also becomes a negative output voltage.

Figure 3 shows the control voltage V_ctrl and the output voltage V_out from the circuit according to the invention as a function of time t.

The control voltage can be characterised by a certain frequency f and a certain duty cycle. The duty cycle can e.g. be 1 :8, which means that the control voltage is high one eighth of the period of time T.

Assume that the condenser Cl is completely discharged at time t = 0 . The control voltage V_ctrι is low, whereby the condenser charges up during the first seven eighths of the time period T. The output voltage V_out is equal to the voltage across the diode Dl, which is approximately equal to 0,7 V if the diode is for example a PN-diode.

During the last one eighth of the time period T the control voltage is high, whereby a polarity reversal occurs at point 2 as explained with reference to Figures la-lc. When this takes place the condenser is fully charged. The output voltage V_out is now equal to -( V_suppι_y - 0,7) V. The output voltage will be held by the charge which is stored in the condenser Cl . The charge is lead to earth through the transistor Tl. The voltage will rise somewhat during the active time period but through a suitable dimensioning of the constituent components in the circuit this variation can be held within specified values V_min and V_max. A Zener diode can also be connected as described with reference to Figure 2 in order to produce a voltage stabilised function.

Figure 4 shows a schematic flow diagram of a method for generating the output voltage (V_out), which output voltage is used during the active time periods and which output voltage is not used during the inactive time periods as described above.

In stage 41 a control voltage V_ctrl is connected to the circuit according to the invention, which control voltage switches between the active and the inactive time periods.

In stage 42 an input voltage V_supply is connected to the circuit.

In stage 43 the input voltage V_supply is converted to the output voltage V_out by means of a DC/DC-converter T 1 , D 1.

In stage 44 the output voltage V_out is generated which comprises the charging up of a storage means Cl with a quantity of charge during the inactive time periods, which quantity of charge produces the output voltage V_out during the active time periods.

Stage 44 comprises also that the DC/DC-converter is switched from the inactive state to the active state depending on the control voltage V_ctrl, whereby the output voltage V_out is obtained as the voltage between a point 2, between the condenser Cl and the diode Dl, and earth, whereby the potential at point 2 takes the value -(input voltage V_supply - ((voltage drop across the diode Dl)) Volts.

In stage 45 a current is produced by means of a current generator I which current generates the quantity of charge which charges up said storage means Cl .

The invention is naturally not limited to the above described embodiments shown in the drawings but can be modified within the scope of the accompanying claims.

Claims

1. Circuit for the generation of an output voltage (V_out) for use during active time periods but not during inactive time periods, characterised in that the circuit comprises

means (CTRL, Tl) for connecting a control voltage (V_ctrl) to the circuit, for switching between the active and the inactive time periods,

means (IN) for connecting an input voltage (V_supply) to the circuit,

a DC/DC-converter (Tl, Dl) for converting the input voltage (V_supply) to the output voltage (V_out),

means for generating the output voltage (V_out), comprising a storage means (Cl), wherein said storage means (Cl) is able to be charged with a quantity of charge during the inactive time periods, for generating the output voltage (V_out) during the active time periods,

a current generator (I, RI , T2) for generating a current, for generating the quantity of charge which charges up said storage means (Cl).

2. Circuit according to claim 1, wherein said storage means (Cl) is formed by a first condenser (Cl) and wherein the current generator (I) comprises a first resistor (RI) which is connected in series with a parallel connection comprising a first branch which comprises the first condenser (Cl) in series with a diode (Dl) and a second branch which comprises a first transistor (Tl), wherein the first condenser (Cl) and the diode (Dl) are connected in parallel with the first transistor (Tl).

3. Circuit according to claim 2, wherein said means for generating the output voltage (V_out) further comprises the diode (Dl) and the first resistor (RI), which resistor is connected to the first condenser (Cl) so that an RC-circuit (RI, Cl) is obtained.

4. Circuit according to claim 1, wherein said storage means (Cl) is formed by a first condenser (Cl) and wherein the current generator (I) comprises a second transistor (T2), which has a drain-connection connected to said means (IN) for connection of the input voltage (V_supply), a source-connection connected to a parallel connection, comprising a first branch which comprises the first condenser (Cl) in series with a diode (Dl) and a second branch which comprises a first transistor (Tl), wherein the first condenser (Cl) and the diode (Dl) are connected in parallel with the first transistor (Tl), and a gate-connection connected together with the source-connection, whereby a saturation current (I_d;Sat) is obtained for charging the first condenser (Cl).

5. Circuit according to claim 1, wherein said storage means (Cl) is formed by a first condenser (Cl) and wherein the current generator (I) comprises a first resistor (RI), a second resistor (R2), a third resistor (R3) and a fourth resistor (R4), a second condenser (C2) and a third transistor (T3),

wherein the third transistor's (T3) collector connection, via the first resistor (RI), is connected to a parallel connection comprising a first branch which comprises the first condenser (Cl) in series with a diode (Dl) and a second branch which comprises the first transistor (Tl), wherein the first condenser (Cl) and the diode (Dl) are connected in parallel with the first transistor (Tl), wherein the third transistor's (T3) emitter connection, via the second resistor (R2), is connected to said means (IN) for connection of the input voltage (V_supp╬╣_y), and

wherein the third transistor's (T3) base connection, via the third and fourth resistors (R3, R4) are connected to said means (CTRL, Tl) for connection of the control voltage (V_ctrl), wherein the second condenser (C2) is connected in parallel with the fourth resistor (R4).

6. Circuit according to any of claims 2, 4 and 5, which comprise a fifth resistor (R5) and a Zener diode (Zl), wherein the Zener diode is connected to a point between the diode (Dl) and the first condenser (Cl) and to the base connection of the first transistor (Tl), and wherein the fifth resistor (R5) is connected to the first transistor's (Tl) base connection and to said means (CTRL) for connection of the control voltage (V_ctrl).

7. Circuit according to any of the previous claims, wherein the DC/DC-converter is switchable between an active state and an inactive state depending on the control voltage (V_ctrl).

8. Circuit according to any of the previous claims, wherein the control voltage (V_ctri) i supplied to the first transistor (Tl) at a control input CTRL.

9. Circuit according to any of the previous claims, wherein the output voltage (V_out) is obtained as the voltage between a point (2), between the first condenser

(Cl) and the diode (Dl), and earth, wherein the potential at the point (2) has the value

- (input voltage (V_supp╬╣_y) - ((voltage drop across the diode (Dl) )) ) V.

10. Method for the generation of an output voltage (V_out), which output voltage is used during an active time period and which output voltage is not used during an inactive time period, which method comprises

connecting a control voltage (V_ctrl) to the circuit, which control voltage switches between the active and inactive time periods,

connecting an input voltage (V_supply) to the circuit,

converting of the input voltage (V_supply) to the output voltage (V_out) by means of a DC/DC-converter (Tl, Dl),

generating an output voltage (V_out)_. comprising the charging up of a storage means (Cl) with a quantity of charge during the inactive time periods, which quantity of charge generates the output voltage (V_out) during the active time periods,

generating a current by means of a current generator (I), which current generates the quantity of charge which charges up said storage means (Cl).

11. Method according to claim 10, wherein the generation of the output voltage (V_out) during the active time periods comprises

the switching of the DC/DC-converter from the inactive state to the active state depending on the control voltage (V_ctrl),

wherein the output voltage (V_out) is obtained as the voltage between a point (2), between said storage means (Cl) and a diode (Dl), and earth, wherein the potential at the point (2) has the value - (input voltage (V_supply) - ((voltage drop across the diode (Dl) )) ) V.

12. Use of the circuit according to any of the claims 1-9, in a radio transmitter comprised in a portable radio equipment, where the radio equipment is used in a radio system where the transmissions occur in bursts, wherein the output voltage (V_0ut) is used as the supply voltage to the power amplifier of the radio transmitter.