Oscillators – Automatic frequency stabilization using a phase or frequency... – Particular error voltage control
Reexamination Certificate
1999-09-27
2001-04-10
Grimm, Siegfried H. (Department: 2817)
Oscillators
Automatic frequency stabilization using a phase or frequency...
Particular error voltage control
C331S025000, C327S157000
Reexamination Certificate
active
06215363
ABSTRACT:
FIELD OF THE INVENTION
This invention relates to phase lock loop circuits and, in preferred embodiments to phase lock loop circuits in power sensitive applications, and communications systems and devices employing the same.
BACKGROUND OF THE INVENTION
A phase lock loop (PLL) circuit is a circuit that is used for the synchronization of signals. Phase lock loops are used in a wide variety of electronic circuits where signals containing analog and digital information are decoded. They may be used in optical tachometers, motor control, television receivers, disk drives, modems, radios, and many other fields.
Phase lock loops can function as synchronizing circuits in which an output frequency is synchronized or locked to a reference frequency.
Some of the most commonly familiar uses of phase lock loops occur within a television receiver. When a signal is sent from a broadcast station to the television receiver the signal must be decoded to represent a picture and sound to be displayed on the television receiver. The television receiver must synchronize the portion of the picture being broadcast that represents the top of the picture to the top of the television screen, the television receiver must also synchronize the left side of the picture being broadcast to the left side of the television screen. The television receiver must also synchronize the colors received in the signal to the colors displayed on the television, so that the red remains red, the blue remains blue, and all the colors match those being broadcast. Somewhat less apparent is the fact that the television must synchronize itself to the sound carrier signal within the television signal so that the sound associated with the picture may be properly demodulated and reproduced through the speakers. All of these synchronizations typically occur through the use of phase lock loops in which the signals which are broadcast from the television transmitter are synchronized to the television circuits which actually process and display these signals.
PLLs are also used in mobile communication applications related to such purposes as frequency generation, signal modulation and demodulation, and data decoding and encoding.
PLLs are unsynchronized when they have no reference signal. In this condition the PLLs are said to be unlocked or out of lock. Phase lock loops generally work by comparing a reference frequency to a generated output frequency and adjusting the output frequency to match the reference frequency. As the output signal is adjusted by the loop there occurs a point at which the frequencies of the output and reference signals match. At this point the signals are sometimes said to be in frequency lock. When the generated frequency is further synchronized in phase with the input frequency the condition is often referred to as phase lock, the locked state, or simply lock. During lock, when the output frequency is synchronized with the reference frequency, the phase error between the output frequency and reference frequency may be very small or even zero. In the lock state the output signal will generally stay in lock until the phase lock loop is somehow perturbed. Some common factors that perturb phase lock loops are loss of the reference frequency, a change in the frequency or phase of the reference frequency, noise on the reference frequency, or noise in the system which disturbs the loop.
There are large number of variations of phase lock loops, and a large number of possible classifications, but they can be grouped into phase lock loops which contain only analog components, and phase lock loops that contain some or all digital components. The common analog or linear phase lock loops were the first to be developed. These phase lock loops ordinarily consist of three parts: 1) the phase detector, which compares the incoming reference frequency to the output frequency, 2) the loop filter, which is typically a low pass type filter built to form an active or passive RC filter, and 3) a voltage controlled oscillator. Digital elements have been gradually integrated into PLLs and hybrid versions have emerged which contain both analog and digital functions. All digital phase lock loop versions have also emerged in which all of the circuit functions are performed by digital circuits. With the advent of inexpensive fast microcontrollers, software versions of the phase lock loop, in which the loop functions are performed by a high speed microprocessor or microcontroller, have been developed. Digital versions of phase lock loops are achieving increasing popularity as their costs drop and their level of integration increases.
The phase lock loop has found extensive use in mobile communication circuits such as portable telephones. They are used to lock to transmitting and receiving frequencies and to recover clock signals from different digital data formats such as return to zero (RZ) and non return to zero (NRZ). As the communications devices, particularly portable telephones, have grown smaller and smaller the desire to obtain more operating time out of smaller and smaller packages has increased. Both small size and long battery life, which can be somewhat opposite constraints, are often seen as desirable characteristics.
There are two ways to address the desire to have smaller portable communications devices with increased operational time. The first is to produce more powerful batteries with a higher energy density and the second is to produce circuitry that consumes less power.
Several approaches have been used to minimize the rate of power consumption by these portable devices. One approach is to minimize the voltage on the circuitry within these portable devices by using circuit components that can operate at lower voltages. Another approach to minimize power consumption is to adopt techniques to enable operation of circuitry within the portable units only part of the time instead of continuously. For example the TDMA (Time Division Multiple Access) protocol allows several portable phones to share the same frequency by broadcasting only part of the time in successive time slots. By broadcasting during a time slot instead of continuously, the output power amplifier can be shut off for most of the time that the phone is active and power can be conserved.
SUMMARY OF THE DISCLOSURE
Accordingly, preferred embodiments of the present invention relate to communications systems and processes which minimizes power consumption while maintaining or enhancing performance.
Phase lock loops commonly comprise Voltage Controlled Oscillators which are adjusted until they match or “lock” to the phase of a reference signal. Commonly phase lock loops function by comparing a reference signal to the Voltage Controlled Oscillator signal and generating a correction signal based on the difference. The correction signal is used to adjust the Voltage Controlled Oscillator until it matches the reference signal. Correction signals may be of a variety of types well known in the art. Correction signals may be a voltage which controls the frequency of the Voltage Controlled Oscillator. Correction signals may also be a constant current pulse which varies in duration. Currently one method of generating current pulses is to employ a “current mirror”. Current mirrors are pairs of current generators in which a first generator is controlled to produce a constant current, and a second generator mirrors the current of the first. To produce current pulses the second current generator is turned on and off with the on off duty cycle being proportional, in the case of a phase lock loop, to the correction signal. The first current generator commonly serves as a mirroring source and functions to set up a bias current for the second current pulse source.
In embodiments of the invention the first current source is switched on and off during the periods when the first current source is not being used as a mirror for the second current source, thereby conserving power. The first current source may be switched on and off via varying synchronizing mechanisms, and may be contro
Ali Akbar
Conta Matteo
Conexant Systems Inc.
Foley & Lardner
Grimm Siegfried H.
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