Television – Receiver circuitry
Reexamination Certificate
1997-08-01
2001-01-23
Powell, Mark R. (Department: 2779)
Television
Receiver circuitry
C348S726000, C348S731000, C455S315000, C455S339000
Reexamination Certificate
active
06177964
ABSTRACT:
TECHNICAL FIELD OF THE INVENTION
This invention relates to television tuner circuits and more particularly to a broadband analog television tuner fabricated in a microcircuit device.
BACKGROUND OF THE INVENTION
One of the most significant costs in television manufacturing is the cost of the tuner. The typical cost of a television (TV) tuner is in the neighborhood of $15.00, which, relative to the cost of the entire television set, is very substantial. Part of the solution to reducing tuner cost is to reduce the number of components in the tuner.
Traditionally, tuners have been comprised of two basic components. The first component performs high frequency to intermediate frequency (RF to IF) conversion. Subsequently, the second component performs IF to baseband conversion. The TV tuner was originally designed for broadcast television reception within a television set, which is essentially a stand-alone unit containing a cathode ray picture tube. So, TV tuners were originally integral parts embedded in a single-purpose device.
Presently, however, state-of-the-art consumer electronic devices use TV tuners that are not a built-in part of a television set. The tuner is a separate element that is connected to a cathode ray picture tube at some point, but the tuner is not an integral part of the monitor. For example, TV tuners may be fabricated on circuit boards and then installed in personal computer (PC) systems, thereby allowing the PC to function as a television set. These tuners convert a radio frequency television signal into a baseband (or low frequency) video signal which can then be passed on to other elements in the PC for video processing applications.
The circuit component that performs the RF-to-IF conversion typically comprises one or two integrated circuits and numerous discrete elements—inductors, capacitors and/or transistors. The IF-to-baseband conversion typically includes another integrated circuit, several filter elements, such as ceramic filters and SAW filters, a series of tuning and control elements, such as resistors and potentiometers, variable inductors and/or capacitors, and some other additional external components. Thus, the complexity of the tuner is fairly high and typically there may be between 100 and 200 elements on a circuit board. Furthermore, state-of-the-art TV tuners still require that each tuner be aligned by manual tuning before leaving the factory. This manual tuning is one of the most expensive costs associated with the manufacturing process and an important factor in the cost of tuners.
Broadcast television tuners of the past have gone through an evolution over a period of more than 60 years. The earliest tuners utilized vacuum tube technology and required that the minimum number of vacuum tubes possible be used due to their cost, power consumption and dimensions. Therefore, passive components, such as resistors, capacitors, inductors and transformers, were used as much as possible in most designs. This style of design continued until about 1960 when TV tuner components, particularly vacuum tubes, began to be replaced by bipolar and MOS transistors. However, the active device count still defined the cost and size limits of TV tuners and active device count minimization continued.
In the early 1970's the integrated circuit became viable as an element in the television tuner and the design techniques were dramatically changed. Many functions of the tuner utilizing only one tube or transistor were being replaced with 4 to 20 individual transistors which could perform the same function with better precision, less space, less power, less heat generation and lower cost. The introduction of the integrated circuit was gradual, first encompassing only low frequency elements and then eventually high frequency active elements. Nonetheless, many passive elements external to the integrated circuits remained in TV tuner designs.
One advance, the SAW (surface acoustic wave) filter, made a significant change in that several manually tuned inductors and capacitors could be removed from the tuners and receive-filtering performance could be improved within a much smaller space and at reduced cost. However, the SAW filter, which is fabricated on a ceramic substrate, cannot be integrated on a silicon wafer with the rest of the active circuitry and must therefore remain a discrete component in the final design. The trend of the 1980's was to miniaturize all of the passive components and simplify their associated manual tuning at the factory. In recent years, TV tuners have been reduced in size from requiring fairly large enclosures, about 2″×5″×1″, to much smaller enclosures, about ½″×2″×⅜″. There is a high premium placed on small size because TV tuners are being used in smaller and smaller computers, television sets and VCRs. As the equipment in which tuners are used becomes smaller, the size of the TV tuner must decrease also.
As the size of the tuner goes down, and as tuners are used in a wider variety of devices, cost becomes more critical and must be reduced as much as possible in order not to represent a large portion of the final product cost. When a tuner is used in a television set, the tuner size is less critical because the television set inherently has a large mass. But when a tuner is used in other electronic equipment, space becomes a premium and the footprint of the tuner becomes critical.
Accordingly, it is one object of the invention to provide a TV tuner which has a relatively low cost and a small footprint for use on a printed circuit board.
It is another object of the present invention to provide a TV tuner that meets or exceeds the performance of state-of-the-art TV tuners while at the same time reducing the number of external components needed, thereby decreasing the complexity of the printed circuit board and the amount of circuit board area needed by the TV tuner.
It is the further object of the present invention to allow for computer control of the TV tuner by a serial bus so that the TV tuner may be controlled by a microcontroller imbedded in the television set, personal computer, or other video device.
It is the further object of the present invention to provide a TV tuner with computer-controlled output impedance characteristics to accommodate different load specifications.
SUMMARY OF THE INVENTION
These and other problems have been solved by a television tuner that receives a broad band of RF signals and converts a desired RF television channel to an IF signal having a picture carrier at 45.75 MHz. To accomplish this, an architecture was chosen to perform an up-conversion of the RF input signal to a higher internal frequency, which allows the present invention to have minimal filtering on the input stages of the receiver. The present invention is therefore able to operate without variable-tuned input filtering. This eliminates the need for precisely controlled variable tuned filters which must be mechanically aligned during manufacture and are subject to variation in performance due to age, temperature, humidity, vibration and power supply performance. This was a critical drawback of previous tuners that had to be eliminated because it is a source of tremendous error and distortion, as well as complexity.
The present invention allows a wide band of frequencies to enter the front end of the tuner circuit without removing frequencies in an input band pass tracking filter. An input filter allows RF signals, typically in the range from 55-806 MHz, to enter the circuit while rejecting high frequency signals above the television band. The input signal then passes through a low noise amplifier that controls the input signal level. Following the input filter and amplifier, the RF signal is converted to an IF signal in a dual mixer conversion circuit. The conversion circuit generally up-converts the RF to a first IF signal and then down-converts the first IF signal to a second IF signal having a 45.75 MHz picture carrier.
It is advantageous to have the up-co
Birleson Vince
Clayton Ken
Taddiken Albert
Fulbright & Jaworski L.L.P.
Microtune, Inc.
Powell Mark R.
Sajous Wesner
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