FOTOWAT-AHMADY ALI
NAVID NASROLLAH S
PHILIPS NORDEN AB (SE)
| EP0308071A2 | 1989-03-22 | |||
| EP0448835A1 | 1991-10-02 | |||
| EP0212987A2 | 1987-03-04 |
| 1. | A prescalar circuit, comprising: an offset generator to receive at least one input signal having an input frequency and to produce at least two offset signals with the input frequency, but offset in transition phase; and an operational circuit coupled to said offset generator to produce at least one output signal by operating on the at least two offset signals. |
| 2. | A prescalar circuit as recited in claim 1, wherein said offset generator produces first and second offset signals offset in transition phase and inverted first and second offset signals, and wherein said operational circuit is a divider circuit for producing at least one output signal with an output frequency lower than the input frequency, from the first and second offset signals and inverted first and second offset signals. |
| 3. | A prescalar circuit as recited in claim 2, wherein said offset generator produces the first offset signal with a first transition from low to high before the second offset signal transitions and a second transition from high to low after the second offset signal transitions, and wherein said operational circuit is a divide by two circuit producing quadrature signals as the at least one output signal. |
| 4. | A prescalar circuit as recited in claim 2, wherein said offset generator receives an input signal and an inverted input signal and comprises: first and second transistors having collectors coupled to said operational circuit to provide the first offset signal and the inverted first offset signal, respectively, having emitters coupled together, and having bases coupled to receive the inverted input signal and the input signal, respectively; a first offset circuit coupled to said first transistor to generate a phase offset from the phase of the inverted input signal in the first offset signal; third and fourth transistors having collectors coupled to said operational circuit to provide the inverted second offset signal and the second offset signal, respectively, having emitters coupled together, and having bases coupled to receive the input signal and the inverted input signal, respectively; and a second offset circuit coupled to said third transistor to generate a phase offset from the phase of the input signal in the inverted second offset signal. |
| 5. | A prescalar circuit as recited in claim 4, wherein said first offset circuit comprises: a first resistor coupling the inverted input signal to the base of said first transistor; and a first current source coupled to the base of said first transistor and said first resistor at a junction therebetween, to draw a current through the first resistor producing an offset voltage at the base of said first transistor, and wherein said second offset circuit comprises: a second resistor coupling the input signal to the base of said third transistor; and a second current source coupled to the base of said third transistor and said second resistor at a junction therebetween, to draw a current through the second resistor producing an offset voltage at the base of said third transistor. |
| 6. | A prescalar circuit as recited in claim 4, further comprising power supply lines coupled to said first through fourth transistors and said operational circuit, wherein said first offset circuit comprises: first and second resistors coupling the emitters of said first and second transistors and having a junction therebetween, said first resistor having a resistance higher than said second resistor; and a third resistor coupled to the junction between said first and second resistors and to one of said power supply lines, and wherein said second offset circuit comprises: fourth and fifth resistors coupling the emitters of said third and fourth transistors and having a junction therebetween, said fourth resistor having a resistance higher than said fifth resistor; and a sixth resistor coupled to the junction between said fourth and fifth resistors and to the one of said power supply lines. |
| 7. | A prescalar circuit as recited in claim 2, wherein said offset generator receives an input signal and an inverted input signal and comprises: first and second transistors having collectors coupled to said operational circuit to provide the first offset signal and the inverted first offset signal, respectively, having emitters coupled together, and having bases coupled to receive the inverted input signal and the input signal, respectively, said first transistor having a threshold voltage smaller than said second transistor; and third and fourth transistors having collectors coupled to said operational circuit to provide the inverted second offset signal and the second offset signal, respectively, having emitters coupled together, and having bases coupled to receive the input signal and the inverted input signal, respectively, said third and fourth transistors constructed so that said third transistor turns ON before said fourth transistor if the bases thereof receive an identical ramp signal. |
The present invention is directed to providing a circuit which an analog divider or radio frequency (RF) prescalar and a quadrature signal generator for use in a digital cellular telephone, or related applications.
A conventional quadrature signal generator including an analog divide by 2 or prescalar circuit using emitter follower logic (EFL) is illustrated in Figure 1. As indicated, the input signals IN and INB are each supplied to the bases of two transistors. Input signal IN is supplied to transistors Q8 and Q18 and input signal INB is supplied to transistors Q9 and Q19. When expected signal levels are received, a signal IN like that illustrated in Figure 2 A will produce the signals I and Q illustrated in Figure 2 A. Since input signal INB is simply the inverse of signal IN, signal INB is not illustrated in Figures 2A and 2B.
Unfortunately, the ideal situation illustrated in Figure 2A will not always exist. The circuit illustrated in Figure 1 has a natural or self-oscillation frequency. If this frequency is near the range of frequencies at which the circuit is operated or tested, a weak or non-existent input signal can produce an output signal at the self-oscillation frequency, instead of at the frequency of the weak input signal. This is a problem in applications where an input signal is not provided at all times that the circuit is applied with power. For example, prescalar circuits used in equipment which has power saving features to power down portions of the circuit that are not in use may result in circuits being powered up in unexpected modes. This can result in the quadrature circuit illustrated in Figure 1 producing a false signal for a period of time before or after an input signal is received.
In addition to a totally false signal like that discussed above, a spiked signal may be produced by a circuit like that illustrated in Figure 1. The mechanism for generation of self-oscillation and spikes is similar. When the voltages supplied to inputs IN and INB are very close to each other (e.g., under weak input signal conditions or when the input levels of IN and INB are passing through zero), the divider circuit illustrated in Figure 1 is converted from a digital flip-flop to an analog high gain circuit with positive feedback,
composed of differential pairs Q8, Q9 and Q18, Q19. It is this positive feedback that causes the unwanted spike or self-oscillation. Of course as soon as the inputs IN and INB have a few millivolts of difference, the circuit converts back to a digital circuit and behaves properly. Typically, as illustrated in Figure 2B, spikes occur in the output signal which is not undergoing a phase change at the time that the other output signal undergoes a phase change and the inputs are passing through a zero crossing. These spikes can affect the performance of circuits which use the output of the quadrature circuit illustrated in Figure 1. The spikes may be detected as a change in phase of the signal, so that the frequency of the quadrature signal is detected as higher than desired. Furthermore, the noise on the input may produce spikes that are formed at irregular intervals, with the result that the false detection of phase changes in downstream circuits will be more erratic than in the example illustrated in Figure 2B.
When the prescalar circuit is part of an integrated circuit, prior to packaging the circuit will commonly undergo wafer testing. Conventionally wafer testing uses test equipment that cannot operate at frequencies as high as the normal operating range of a high frequency circuit, due to excessive inductance in the length of the probes used in wafer testing. As a result, wafer testing is done at lower frequencies. The spikes or self- oscillation can disrupt this essential test. A solution is then needed to eliminate the unwanted spikes and self-oscillation.
It is an object of the present invention to provide a prescalar circuit having a spike-free output. It is also an object of the present invention to provide a prescalar circuit that will not oscillate even if the input signal level is weak or the input signal lines are an open circuit.
It is another object of the present invention to provide quadrature signal outputs that do not have spikes caused by a prescalar circuit. It is an additional object of the present invention to provide a quadrature signal generating circuit which does not produce false output signals during normal operation or testing.
According to the present invention a prescalar circuit is provided which comprises
an offset generator to receive at least one input signal having an input frequency and to produce at least two offset signals with the input frequency, but offset in transition phase; and an operational circuit coupled to said offset generator to produce at least one output signal by operating on the at least two offset signals.
By offsetting the transition phase at zero-crossings of the input signal, the operational circuit will operate in a digital mode also for weak input signals or if no input signal is present but only noise at given frequencies. Herewith, self-oscillation of the operational circuit and/or generation of spikes at zero-crossings is avoided. These together with other objects and advantages which will be subsequently apparent, reside in the details of construction and operation as more fully hereinafter described and claimed, reference being had to the accompanying drawings forming a part hereof, wherein like numerals refer to like parts throughout.
Figure 1 is a schematic circuit diagram of a conventional quadrature signal generator with an emitter follower logic divide by 2 flip-flop;
Figures 2A and 2B are graphs of signals in the circuit illustrated in Figure
1; Figure 3 is a schematic circuit diagram of an embodiment of a quadrature signal generator with an emitter follower logic divide by 2 analog divider according to the present invention;
Figure 4 is a graph of signals in the circuit illustrated in Figure 3; and Figures 5A and 5B are schematic circuit diagrams of alternative methods of generating an offset voltage for a quadrature signal generator according to the present invention.
As illustrated in Figure 3, a prescalar circuit according to the present invention is similar to the prescalar circuit in the conventional quadrature signal generating circuit illustrated in Figure 1. The difference between the conventional circuit illustrated in Figure 1 and the quadrature signal generating circuit illustrated in Figure 3 is the addition of dual offset generators at the inputs. Instead of supplying the input signals IN, INB directly to the bases of transistors Q8, Q9, Q18 and Q19, the input signals IN, INB are supplied to the
dual offset generators. The upper offset generator illustrated in Figure 3 produces signal CLKI and its inverse CLKIB which are supplied to the bases of transistors Q8 and Q9, respectively. The lower offset generator illustrated in Figure 3 produces outputs CLKQ and its inverse CLKQB which are supplied to the bases of transistors Q19 and Q18, respectively. In the upper offset generator which produces signals CLKI, CLKIB, transistors Q29, Q30 form a differential pair acting as an amplifier. Transistors Q34, Q35 are emitter follower buffers. The current source Q27 draws current from the resistor R25 to produce an offset voltage. In the preferred embodiment the current and resistance are selected to produce and offset voltage of 10 millivolts. The offset voltage causes transistor Q29 to turn OFF before input signal INB crosses zero volts, i.e., earlier than transistor Q39 in the lower offset generator turns OFF due to the drop in voltage of input signal INB. Due to differential coupling, transistor Q30 turns ON when transistor Q29 turns OFF. As a result, signal CLKI go up before signal CLKQ.
The lower offset generator which produces signals CLKQ, CLKQB is constructed in a similar, but symmetrical manner compared to the upper offset generator. Transistor Q40 and resistor R33 produce a similar offset voltage which causes transistor Q38 to turn OFF before transistor Q30 in the upper offset generator, as the input signal INB crosses zero. As a result, signal CLKQ will go from high to low before signal CLKI.
Referring to Figure 4, it is clear that CLKI always changes its state before the positive slope zero crossing of IN and after the negative slope zero crossing of IN. On the other hand, CLKQ changes state after the positive slope zero crossing of IN and before the negative slope zero crossing of IN. In a state where INB equals IN, i.e., during zero crossings, Q30 is ON and Q29 is OFF. Similarly, Q39 will be ON and Q38 will be OFF. This is made possible by resistors R33, R25 and current sources Q27, Q40 which force the bases of Q29 and Q38 to be lower than the bases of Q30 and Q39, respectively. This in turn causes the differential pairs Q8, Q9 and Q18, Q19 to be unbalanced when IN equals INB. In the prior art circuit these differential pairs were balanced under these conditions causing the circuit to become a high gain linear amplifier with positive feedback.
Due to the addition of the offset generators in a prescalar circuit according to the present invention, transistor Q8 will be ON and transistor Q9 will be OFF during the transition of transistors Q18 and Q19 in both directions. As a result, the positive feedback condition is eliminated, thereby preventing self-oscillation and producing a spike-free output.
The present inventic is not limited to the embodiment illustrated in Figure 3. For example, Figure 3 illustrates an EFL circuit, but the invention may be used in
prescalar and quadrature circuits implemented using current mode logic (CML), etc. In addition, other methods of producing an offset may be used.
In the embodiment illustrated in Figure 3, a fixed current flows through two of four resistors at the inputs of the offset generators to produce an offset. Two alternatives to this method of producing an offset are shown schematically in Figures 5A and 5B. In the alternative embodiment illustrated in Figure 5A, the areas of the differential pair transistors are different. The area corresponding to reference character XI is twice as large as the area corresponding to reference character X2. The difference in the areas of the two transistors which form the differential pair illustrated in Figure 5A will cause the tail current to be split unequally (with a 2: 1 ratio) when the differential input to the differential pair is zero. This will cause an offset at the two emitter follower outputs. As a result, if an identical ramp signal is supplied to the bases of the differential pair transistors illustrated in Figure 5A, the left-hand transistor will tum ON before the right-hand transistor.
In the alternative embodiment illustrated in Figure 5B, the same effect is achieved by resistor ratios where one emitter resistor is X times larger than the other emitter resistor. Again under a zero volt differential input, the left-hand transistor will have less current than the right-hand transistor in the differential pair illustrated in Figure 5B. This will cause the two output emitter followers to have unequal output voltages.
The circuits shown in Figures 5A and 5B are functionally equivalent to the offset generator circuits added to Figure 3. All of these circuits will produce the same offset signals which produce CLKI, CLKIB, CLKQ and CLKQB illustrated in Figure 4.
The many features and advantages of the invention are apparent from the detailed specification and, thus, it is intended by the appended claims to cover all such features and advantages of the invention which fall within the true spirit and scope of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation illustrated and described, and accordingly all suitable modifications and equivalents may be resorted to, falling within the scope of the invention.
Reference Number List
C1-C7 Capacitors
CLKI, CLKIB, CLKQ, CLKQB Internal signal lines
IN, INB Input signal lines
OUTI, OUTQ Output signal lines
Q1-Q43 Transistors
R1-R39 Resistors
VCC, GND Power supply lines
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