Input buffer circuit for RF phase-locked loops

An input buffer circuit includes a first amplifier having low load impedance and a second amplifier having high load impedance. The output signals of the input buffer circuit have wide bandwidth, although the input buffer circuit has two stage amplifiers. In addition, the bandwidth can be controlled by resistors as an equivalent active inductance of the input buffer circuit. Further, the input buffer circuit can reduce the power consumption compared with conventional input buffer circuits, since the input buffer circuit according to the present invention uses a first switching current of the first amplifier as well as a second switching current of the second amplifier to load output signals.

FIELD OF THE INVENTION

The present invention relates to a communication system, and more particularly to an input buffer circuit for radio frequency (RF) phase-locked loops(PLLs).

BACKGROUND OF THE INVENTION

Communication systems for connecting persons to allow them to transmit and receive information back and forth are becoming increasingly powerful. In fact, certain types of systems, such as modems for performing data communication and telephones for performing voice communication, have become indispensable to many users. Generally, communication systems are classified as either wired communication systems which use data transmission lines or wireless communication systems which transmit data using electromagnetic transmissions such as radio frequency (RF) transmissions.

In portable systems that include wireless communication capability, such as pagers, cellular telephones, personal communication service (PCS) phones, personal digital assistants (PDA), and portable computers including laptops and notebook computers, there are several important considerations. These include battery life and, therefore, power consumption, as well as the weight and volume of the system. These factors are all affected by the size and type of integrated circuits that make up the systems in general and their resident communication systems in particular. The size and type of traditionally external components is also an important factor. With the developments made in integrated circuit technology, more and more components which were traditionally considered external components are being embedded in integrated circuits.

FIG. 1 is a block diagram illustrating a conventional communication receiver 100 . Referring to FIG. 1 , the communication receiver 100 comprises an antenna 1 , a speaker 2 , a radio frequency (RF) amplifier 10 , a mixer 20 , an intermediate frequency (IF) amplifier 30 , a base band analog processor (BBA) 40 , and an RF phase-locked loop (PLL) 95 . The PLL 95 includes a voltage-controlled oscillator VCO 50 , a frequency divider 75 , a phase detector 80 and a filter 90 .

The RF amplifier 10 amplifies an RF signal having radio band frequency received from the antenna 1 . The mixer 20 mixes the RF signal from the RF amplifier 10 with an oscillating signal generated by the VCO 50 to generate an intermediate frequency (IF) signal having intermediate band frequency. The IF amplifier 30 amplifies the IF signal from the mixer 20 . The BBA processor 40 receives the IF signal from the IF amplifier 30 and converts the IF signal to a base band analog (BBA) signal having base band frequency. The BBA signal is provided as an output to the speaker 2 .

Generally, phase-locked loops (PLL) can be classified according to their frequency characteristics as radio frequency (RF) phase-locked loops, such as PLL 95 in FIG. 1 , and low frequency (LF) PLLs. For example, referring to FIG. 2 , which is a detailed block diagram illustrating the RF PLL 95 shown in FIG. 1. , recent mobile telecommunication systems such as the cellular phone and the PCS phone use an RF PLL 95 having a prescaler 60 as a principal part of their systems. The LF PLL does not require a prescaler, since the LF PLL is operated at low frequency.

Referring to FIG. 2 , the RF PLL 95 comprises the VCO 50 , the phase detector 80 , the filter 90 and the frequency divider 75 , which includes the prescaler 60 and a divider 70 . In the RF PLL 95 shown in FIG. 2 , the VCO 50 generates an oscillating signal having the radio band frequency. The frequency divider 75 divides the frequency of the oscillating signal from the VCO 50 by a predetermined divisor, for example, N, and outputs a divided oscillating signal Ffeed to the phase detector 80 . The prescaler 60 is used for pre-dividing the frequency of the oscillating signal from the VCO 50 , and the divider 70 is used for dividing the pre-divided oscillating signal from the prescaler 60 .

The prescaler 60 divides the oscillating signal, typically having a frequency in the Gigahertz (GHz) range, and outputs a pre-divided oscillating signal, typically having a frequency in the tens of Megahertz (MHz), to the divider 70 . The divider 70 divides the pre-divided oscillating signal and outputs a further divided oscillating signal to the phase detector 80 . The prescaler 60 typically includes emitter coupled logic (ECL) circuitry which is applicable for high speed operation.

The phase detector 80 compares a reference input signal Fref having a reference frequency with the divided oscillating signal Ffeed from the frequency divider 75 , to generate a control signal which is applied to the VCO 50 through the filter 90 , so as to control the VCO 50 .

The prescaler 60 composed of the ECL circuitry, comprises an input buffer circuit for amplifying the low-level oscillating signal to the ECL level. The input buffer circuit is capable of operating in the Ghz frequency range and is used to provide a wide input sensitivity to the prescaler 60 . One example of the input buffer circuit for the ECL prescaler is set forth in a paper entitled, A 3-mW 1.0-Ghz Silicon-ECL Dual-Modulus Prescaler IC , by Moriaki Mizuno, Hirokazu Suzuki, Masami Ogawa, Kouji Sato, and Hiromich Ichikawa, published in the December, 1992 issue of IEEE JOURNAL OF SOLID STATE CIRCUITS, vol. 27, No. 12, pages 1794-1797.

FIG. 3 is a circuit diagram which illustrates an input buffer circuit 65 included in the prescaler 60 shown in FIG. 2 , and which is disclosed in the above paper. Referring to FIG. 3 , the input buffer 65 comprises a first amplifier 61 , a second amplifier 62 , and a output driving circuit 63 . The first amplifier 61 receives an oscillating signal IN and an inverted oscillating signal INB from the VCO 50 . The input signals IN and INB have 50 mV-0.5V of peak voltage, and a high frequency response of more than 1 GHz. Transistors Q 1 , Q 2 , Q 3 and Q 4 are included in the first and the second amplifiers 61 and 62 . They operate as switches when the voltage of the input signal IN is higher than 100 mV, for example, and operate as amplifiers when the voltage of the input signal IN is 50 mV or less, for example. The bandwidths of output signals OUT and OUTB of the input buffer circuit 65 are restricted by parasitic capacitances existing on nodes N 1 , N 2 , N 3 and N 4 , and load resistors RL 1 , RL 2 , RL 3 and RL 4 . The output signals OUT and OUTB are digitized by the switching operation of the transistors Q 1 , Q 2 , Q 3 and Q 4 , and then they are outputted to the phase detector 80 through the output driving circuit 63 .

FIG. 4 is a diagram illustrating simulated output characteristics of the input buffer 65 shown in FIG. 3 . The plot of FIG. 4 illustrates a characteristic of the input buffer generated by a computer simulation, such as SPICE, with circuit parameters set as follows: VDD 3V, VBB 1 1.5V, RL 3 RL 4 1.75 k , IEE 1 IEE 2 200 A, and IEE 3 IEE 4 50 A. The simulated frequency response with this current has adequate gain (for example, 14 dB) up to 1.0 Ghz as shown in FIG. 4 . The output characteristics of the input buffer 65 will be described in detail below, including comparing them with the output characteristics of an input buffer according to an embodiment of the present invention.

To obtain the output characteristics illustrated in FIG. 4 , switching voltages across load resistors RL 1 , RL 2 , RL 3 and RL 4 must be kept above 300 mV in the input buffer circuit 65 , so as to satisfy the ECL output characteristics. That is, the first and the second switching voltages obtained by multiplying a first switching current IEE 1 and the respective load registers RL 1 and RL 2 must be kept above 300 mV in the first amplifier 61 . Similarly, the third and the fourth switching voltages obtained by multiplying a second switching current IEE 2 and the respective load registers RL 3 and RL 4 must be kept above 300 mV in the second amplifier 62 .

Several problems occur in the conventional input buffer circuit 65 in connection with achieving both low power consumption and a wide bandwidth, while satisfying the above described restriction related to the switching voltages. For example, when the resistance of the load resistors RL 1 , RL 2 , RL 3 and RL 4 is reduced, the output bandwidth of the input buffer circuit 65 is enlarged. However, at the same time, the power consumption of the input buffer circuit 65 increases, because the switching currents IEE 1 and IEE 2 are increased so as to keep the switching voltages above 300 mV. Also, when the switching currents IEE 1 and IEE 2 are reduced, the power consumption of the input buffer circuit 65 is reduced. But, the output bandwidth of the input buffer circuit 65 becomes narrower because the resistance of the load resistors RL 1 , RL 2 , RL 3 and RL 4 are increased to keep the switching voltages above 300mV.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide an input buffer circuit of a prescaler included in an RF PLL, having a wide bandwidth and low power consumption characteristics.

It is another object of the present invention to provide an input buffer circuit capable of controlling its output bandwidth.

In order to attain the above objects, according to an aspect of the present invention, there is provided an input buffer circuit which includes a first switching means having cascode transistors. The first switching means receives a first switching current from a power supply voltage source, switches the first switching current in response to the externally applied oscillating signal, and generates a first and a second switching signal by converting the first switching current into a first and a second switching voltage. A second switching means receives a second switching current from the power supply voltage source and switches the second switching current in response to the first and the second switching signals. A loading means generates a third and a fourth switching signal by converting both the first and the second switching currents into a third and a fourth switching voltage. An output driving means outputs a first and a second output signal in response to the third and the fourth switching signals, respectively.

According to another aspect of this invention, there is provided a cascode circuit having a first and a second resistor used as an equivalent inductance. The output bandwidth of the input buffer circuit can be controlled by the resistors.

DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION

FIG. 5 is a schematic circuit diagram which illustrates one embodiment of an input buffer circuit 650 according to the present invention. Referring to FIG. 5 , the input buffer circuit 650 comprises a loading circuit 610 , a first amplifier 620 , a second amplifier 630 , and an output driving circuit 640 .

The first amplifier 620 is used for receiving a first switching current IEE 1 from a power supply voltage source VDD, switching the first switching current IEE 1 in response to the externally inputted oscillating signals IN and INB, and generating a first and a second switching voltage VN 1 and VN 2 by converting the first switching current IEE 1 into the voltages.

For performing these operations, the first amplifier 620 includes a cascode circuit 621 , a loading section 622 , and a switching circuit 623 . The circuit 621 is in cascode with the loading section 622 . The circuit 621 supplies the first switching current IEE 1 for the switching circuit 623 through the loading section 622 , without loss. The loading section 622 generates a first and a second switching voltage VN 1 and VN 2 at circuit nodes N 1 and N 2 , respectively, by converting the first switching current IEE 1 into the voltages, respectively, in response to the switching operation of the switching circuit 623 . The switching circuit 623 switches the first switching current IEE 1 , selectively, in response to externally applied oscillating signals IN and INB.

The circuit 621 in cascode with the loading section 622 , includes a pair of cascode transistors Q 11 and Q 12 and resistors RBB 3 and RBB 4 . The first cascode transistor Q 11 has a base coupled to the resistor RBB 3 , a collector couple to a node N 4 , and an emitter. The second cascode transistor Q 12 has a base coupled to the resistor RBB 4 , a collector coupled to a node N 3 , and an emitter. The resistors RBB 3 and RBB 4 are commonly coupled to a bias voltage source VBB 2 .

The loading section 622 includes two load resistors RE 1 and RE 2 . The first load resistor RE 1 is coupled between the emitter of the first cascode transistor Q 11 and node N 1 . The second load resistor RE 2 is coupled between the emitter of the second cascode transistor Q 12 and node N 2 .

The switching circuit 623 includes two switching transistors Q 1 and Q 2 , two resistors RBB 1 and RBB 2 , and a constant current source IEE 1 . The first switching transistor Q 1 has a base coupled to the resistor RBB 1 and a first input terminal for receiving an inversed oscillating signal INB from a voltage-controlled oscillator (VCO), a collector coupled to the node N 1 , and an emitter. The second switching transistor Q 2 has a base coupled to the resistor RBB 2 and a second input terminal for receiving an oscillating signal IN from the VCO, a collector coupled to the node N 2 , and an emitter. The emitters of the transistors Q 1 and Q 2 are commonly coupled to the first current source IEE 1 , and the resistors RBB 1 and RBB 2 are commonly coupled to a bias voltage source VBB 1 .

The second amplifier 630 receives a second switching current IEE 2 from the power supply voltage source VDD and switches the second switching current IEE 2 in response to the first and the second switching voltages VN 1 and VN 2 at nodes N 1 and N 2 , respectively. The second amplifier 630 includes two switching transistors Q 3 and Q 4 and a second constant current source IEE 2 . The third switching transistor Q 3 has a base coupled to the node N 1 , a collector coupled to the node N 3 , and an emitter. The fourth switching transistor Q 4 has a base coupled to the node N 2 , a collector coupled to the node N 4 , and an emitter. The emitters of the switching transistors Q 3 and Q 4 are commonly coupled to the second current source IEE 2 .

The loading circuit 610 generates a third and a fourth switching voltage VN 3 and VN 4 at nodes N 3 and N 4 , respectively, by changing both the first and the second switching currents IEE 1 and IEE 2 into the voltages, in response to the switching operation of the second amplifier 630 . The loading circuit 610 includes a first loading resistor RL 1 and a second loading resistor RL 2 . The first loading resistor RL 1 is coupled between a power supply voltage source VDD and the node N 3 , and the second loading resistor RL 2 is coupled between the power supply voltage source VDD and the node N 4 .

The output driving circuit 640 outputs the first and the second output signals OUT and OUTB in response to the third and the fourth switching voltages VN 3 and VN 4 from the loading circuit 610 . The output driving circuit 640 includes two transistors Q 5 and Q 6 and two current source IEE 3 and IEE 4 . The transistor Q 5 has a base coupled to the node N 3 , a collector coupled to the power supply voltage source VDD, and an emitter coupled to a node N 5 . The third current source IEE 3 and the first output terminal for outputting the inverted output signal OUTB of the input buffer circuit 650 are connected to the node N 5 . The transistor Q 6 has a base coupled to the node N 4 , a collector coupled to the power supply voltage source VDD, and an emitter coupled to a node N 6 . The fourth current source IEE 4 and the second output terminal for outputting the output signal OUT of the input buffer circuit 650 are connected to the node N 6 . In the input buffer circuit 650 , the current sources IEE 1 , IEE 2 , IEE 3 and IEE 4 are commonly couple to a ground voltage source GND, so as to sink their respective currents.

The input buffer circuit 650 included in a prescaler amplifies the oscillating signal from the VCO (referring to FIG. 2 ). The first amplifier 620 of the input buffer circuit 650 compares the oscillating signal IN with the inverted oscillating signal INB and generates the first and the second switching voltages VN 1 and VN 2 as comparison results.

For example, it is assumed that only oscillating signal IN is applied to the base of the transistor Q 2 , when the transistors Q 1 , Q 2 , Q 11 and Q 12 are operated in an active region by the bias voltage sources VBB 1 and VBB 2 . In addition, it is assumed that the base of the transistor Q 1 is electrically grounded through a capacitor (not shown).

Before the oscillating signal IN is applied, the first and the second switching voltages VN 1 and VN 2 from the node N 1 and N 2 are described as follows:

As shown in equation (1), the switching voltages VN 1 and VN 2 are obtained by subtracting the base-emitter voltages of the transistors Q 11 and Q 12 from the bias voltage VBB 2 , respectively. In that case, it is assumed that respective current gains of the transistors Q 11 and Q 12 are sufficiently great. With these assumptions, the third and the fourth switching voltages VN 3 and VN 3 from the node N 3 and N 4 are described as follows:

As shown in equation (2), the third and the fourth switching voltages VN 3 and VN 4 are obtained by subtracting the voltage corresponding to the load resistors RL 1 and RL 2 from the power supply voltage source VDD, respectively.

Then if an oscillating signal IN swing in low level is inputted to the base of the transistor Q 2 , the first switching transistor Q 1 is turned on and the second switching transistor Q 2 is turned off, respectively. In that case, switching voltages VN 1 and VN 2 from the nodes N 1 and N 2 are described as follows:

In the second amplifier 630 , the transistors Q 3 and Q 4 perform switching operations in response to the first and the second switching voltages VN 1 and VN 2 from the nodes N 1 and N 2 , respectively. As shown in equation (3), the first switching voltage VN 1 has low voltage level, and the second switching voltage VN 2 has high voltage level. Thus, the third switching transistor Q 3 receiving the first switching voltage VN 1 is turned off, and the fourth switching transistor Q 4 receiving the second switching voltage VN 2 is turned on. Therefore, the loading circuit 610 generates switching voltages VN 3 and VN 4 from the nodes N 3 and N 4 in response to the switching operation of the second amplifier 630 , as described in equation (4).

As shown in equation (4), the loading circuit 610 according to the present invention uses the first switching current IEE 1 as well as the second switching current IEE 2 to generate the switching voltages VN 3 and VN 4 . The summation of the first and the second switching currents, i.e., IEE 1 IEE 2 , across the second load register RL 2 is equal to the switching current IEE 2 of the conventional input buffer circuit 65 shown in FIG. 3 . Thus, the input buffer circuit 650 can reduce the power consumption about two times compared with the conventional input buffer circuit 65 , since the loading circuit 610 reuses the first switching current IEE 1 to generate the switching voltages VN 3 and VN 4 , which will be described in detail below.

The third and the fourth switching voltages VN 3 and VN 4 are applied to the base of the transistors Q 5 and Q 6 of the output driving circuit 640 , respectively. The transistors Q 5 and Q 6 output the switching voltages VN 3 and VN 4 after lowering them by the base-emitter voltage of the transistors Q 5 and Q 6 . As described above, the third switching voltage VN 3 has high voltage level, and the fourth switching voltage VN 4 has low voltage level, so that the output driving circuit 640 outputs the first output signal OUTB having high voltage level, and second output signal OUT having low voltage level.

In contrast, if an oscillating signal IN swing in high level is applied to the base of the transistor Q 2 when the nodes N 1 , N 2 , N 3 and N 4 have such output voltages VN 1 , VN 2 , VN 3 and VN 4 , respectively, the first switching transistor Q 1 is turned off and the second switching transistor Q 2 is turned on in response to the oscillating signal IN. In that case, the first amplifier 620 generates switching voltages VN 1 and VN 2 as described in equation (5).

In the second amplifier 630 , the switching transistors Q 3 and Q 4 perform switching operations in response to the switching voltages VN 1 and VN 2 from the nodes N 1 and N 2 , respectively. Thus, the third transistor Q 3 is turned on and the fourth transistor Q 4 is turned off. Therefore, the load circuit 610 generates switching voltages VN 3 and VN 4 as described in equation (6), in response to the switching operation of the second amplifier 630 .

The third and the fourth switching voltages VN 3 and VN 4 are applied to the base of the transistors Q 5 and Q 6 of the output driving circuit 640 , respectively. The transistors Q 5 and Q 6 output the switching voltages VN 3 and VN 4 after lowering them by the base-emitter voltage of the transistors Q 5 and Q 6 . As shown in equation (6), the third switching voltage VN 3 has low voltage level, and the fourth switching voltage VN 4 has high voltage level, so that the output driving circuit 640 outputs the first output signal OUTB having low voltage level, and second output signal OUT having high voltage level.

For performing above described operations, the loading circuit 610 reuses the first switching current IEE 1 with the second switching current IEE 2 to load the third and the fourth switching voltages VN 3 , VN 4 , VN 3 , VN 4 , VN 3 and VN 4 into the output driving circuit 640 . Thus, the input buffer circuit 650 can reduce the current consumption about two times compared with the conventional input buffer circuit.

For example, when the load resistors RL 1 , RL 2 , RL 3 and RL 4 of the conventional input buffer circuit 65 shown in FIG. 3 , and the load resistors RL 1 and RL 2 of the input buffer circuit 650 according to the present invention are 1 k , respectively, assume that the respective switching voltages corresponding to the load resistors of the conventional input buffer circuit 65 and the input buffer circuit 650 are 300 mV. In the conventional input buffer circuit 65 , the currents through the load registers RL 1 , RL 2 , RL 3 and RL 4 are 150 A, respectively. Thus, the conventional input buffer circuit 65 consumes 600 A during the switching operations of the first and the second amplifier 61 and 62 . Otherwise, in the input buffer circuit 650 , the currents through the load registers RL 1 and RL 2 are 150 A, respectively. Thus, the input buffer circuit 650 according to the present invention consumes 300 A during the switching operations of the first and the second amplifier 620 and 630 . Therefore, the input buffer circuit 650 according to the present invention can reduce the power consumption by about half compared with the conventional input buffer circuit 65 .

In addition, the resistors RBB 3 and RBB 4 are used as equivalent inductance when the frequency is increased, so that the output bandwidth of the output signals OUT and OUTB can be enlarged by controlling the resistors RBB 3 and RBB 4 . This inductance effect realized by resistors is disclosed generally in Analysis and Design of Analog Integrated Circuits, by P. R. Gray and R. G. Meyer, published in 1992, Wiley, New York, pages 424-431. The input buffer circuit 650 can output the output signals OUT and OUTB having wide bandwidth by forming a low impedance base-emitter voltage VBE loop, when the transistors Q 11 and Q 12 of the first amplifier 620 and the transistors Q 3 and Q 4 of the second amplifier 630 can neglect voltage drops across the resistors RBB 3 , RBB 4 , RE 1 and RE 2 .

FIG. 6 is a schematic plot illustrating output characteristics of the input buffer shown in FIG. 5 . The input buffer circuit 650 is simulated by a circuit simulation computer program, such as SPICE, with VDD 3V, VBB 1 1.5V, VBB 2 3V, IEE 1 IEE 2 100 A, RL 3 RL 4 1.75 k , and RE 1 RE 2 0.1 k .

Referring to FIG. 6 , a passband flatness of the input buffer circuit 650 is superior to that of the conventional input buffer circuit 65 shown in FIGS. 3 and 4 . In addition, the input buffer circuit 650 can control the flatness at a band edge by adjusting the resistance of the resistors RBB 3 and RBB 4 . Further, the input buffer circuit 650 has the gain above 10 dB and sufficiently wide bandwidth.

As described above, the input buffer circuit 650 comprises the first amplifier 620 having low load impedance and the second amplifier 630 having high load impedance. Thus, the output signals OUT and OUTB of the input buffer circuit 650 have wide bandwidth, although the input buffer circuit 650 has two stage amplifiers 620 and 630 . In addition, the bandwidth can be controlled by the resistors RBB 3 and RBB 4 used as equivalent active inductance of the input buffer circuit 650 . Further, the loading circuit 610 loads the third and the fourth switching voltages VN 3 and VN 4 into the output driving circuit 640 by using both switching currents IEE 1 and IEE 2 , so that the input buffer circuit 650 can reduce the power consumption to about half of that compared with the conventional input buffer circuit 65 shown in FIG. 3 .