JP2006502669A - Apparatus, method and article for generating electromagnetic treatment - Google Patents

Abstract

Generation devices, methods, and articles are shown for electromagnetic wave modification. By using various wave characteristics, such as amplitude, to regulate the current source, current is output that can be used in any number of ways, such as driving an antenna or other load. The

Description

  The present invention relates generally to electromagnetic processing, and more specifically to electromagnetic wave attenuation or amplification.

  Controlled attenuation or amplification of electromagnetic waves has many uses. For example, intelligence attenuates and / or amplifies ("modifies") electromagnetic properties, as seen when modulating the amplitude, frequency, or phase of current or radio frequency (RF) to transmit data. ) Can be transmitted along the wave. As another example, as can be seen when modulating the voltage or current of a circuit, power can be transmitted along the wave in a controlled manner by attenuating and / or amplifying electromagnetic characteristics. . Furthermore, applications can be combined, such as when intelligence can be transmitted by waves by modifying power characteristics.

  The modification of the electromagnetic characteristics can be achieved by digital or analog techniques. Digital and analog attenuation and / or amplification can also be combined. That is, the same wave can be subjected to various types of digital and / or analog attenuation and / or amplification in the system to accomplish the desired task.

  However, it may be difficult to modify the characteristics of electromagnetic waves. For example, selecting appropriate techniques or components to modify wave characteristics may be difficult for several reasons. One of those reasons involves the type of wave being modified. For example, low frequencies such as 60 Hz power waves may require different correction techniques than high frequency waves such as 24 GHz radar waves. Thus, it is common to use different components with different characteristics for different waves. For example, switching semiconductors used in computers for 60 Hz power waves have different power handling characteristics than those used in 24 GHz radar systems. However, if similar or standard techniques and / or components can be used for some types of waves, they are useful in the field of electromagnetic wave correction by simplifying the design techniques.

  One attempt at standard techniques and components recently used is to use wave characteristics as information to modify the wave. For example, by transforming a wave into polar coordinates with amplitude and phase characteristics, either or both characteristics can be used and / or manipulated in a manner that provides a standardized technique for various wave frequencies. It is possible. However, such trials so far have been limited by the difficulty of application. For example, attempts to use multiple amplifiers have presented difficulties associated with amplifier combinations. Specifically, components such as transformers or quarter wave lines are used to sum the output of the amplifiers to drive the load. These components increase the cost and size of the amplifier array.

  Therefore, it is useful in the field of electromagnetic processing that wave characteristics can be used to attenuate and / or amplify waves in an efficient manner.

  Embodiments of the present invention include devices, methods, and articles for generating electromagnetic wave modifications. Preferred embodiments provide techniques and / or components that use wave characteristics and modify various types of waves to modify waves. In these embodiments, two or more independently controllable current sources are used to generate an output wave that is a modification of the input wave. These current sources are regulated by the characteristics of the input wave.

  Embodiments of the present invention include devices, methods, and articles that generate electromagnetic wave attenuation and / or amplification (“modification”) according to wave characteristics.

  FIG. 1 shows a preferred embodiment. An input wave is provided to the digital signal processor 10. The digital signal processor 10 comprises an analog-to-digital converter 11 that digitizes the waves, for example by using Cartesian coordinates or I, Q data. The orthogonal polar converter 12 then receives the I and Q data and converts it to polar coordinates. Note that in other embodiments, if desired, a digital representation of the wave can be provided to the quadrature converter. In those embodiments, the digital display can be generated in any of several ways known in the art. Also, although this embodiment is described as used for digital waves and I, Q data and polar data, those skilled in the art will not be limited to this, and any digital waveform or analog waveform or It will be appreciated that combinations can be used.

  Returning now to the embodiment of FIG. 1, the orthogonal polar converter 12 outputs a digital wave in polar coordinates, for example in the form of R, P (sin), and P (cos). In this example, the R coordinate represents a wave amplification characteristic. P (sin) coordinates and P (cos) coordinates represent the phase characteristics of the wave. It should be noted that “characteristic” as used herein refers to electromagnetic wave characteristics such as frequency, voltage, amplitude (including magnitude and envelope), phase, current, waveform, or pulse. Other embodiments can derive one or more wave characteristics from the input wave as desired.

Referring temporarily to FIG. 2, a schematic diagram of a wave transformed according to the embodiment of FIG. 1 is shown. The input wave was converted into a magnitude component m with the magnitude characteristic of the input wave over period t ₁ and a phase component p with phase characteristics for the carrier over the same period. The output wave b is shown after amplification according to the preferred embodiment. Note that the time period for this and other embodiments is as desired. For example, embodiments can derive wave magnitude and phase characteristics using various sampling rates to maximize wave resolution, maximize operating speed, etc. . These sampling rates can also be determined dynamically in various embodiments so that the sampling rates change during operation. In a preferred embodiment, the input wave divisions are synchronized to maximize output accuracy and minimize any distortion.

Returning now to FIG. 1, the amplitude and phase characteristics are then transmitted via separate paths. Amplitude characteristics of the input wave, along the path ^{a m} via the converter 13, a quantization bits _{B 0} is the least significant bit from the most significant bit ( "MSB") ( "LSB") to _{B n-1} Converted into a digital pulse comprising a digital word. The digital word can be variable length in various embodiments. In general, as the word becomes longer, the reproduction accuracy of the input wave improves. The digital word provides attenuation and / or amplification control in the manner further described below. Of course, as further described below, in other embodiments, differently configured digital words can be used, as well as other types of derivation and / or provision of amplitude or other wave characteristics. It is.

In the embodiment of FIG. 1, seven control component lines a ^m 1 to a ^m 7 are shown exiting from the converter 13. The number of these control component lines depends in a preferred embodiment on the resolution of the word. In this preferred embodiment, the word has a 7-bit resolution. In Figure 1, for ease of seeing the drawing, the control component lines is noted to be integrated into a single path a ^m reaching the control component 22A～g. However, in this embodiment, as will be further described below, the control component lines are not integrated, but instead are supplied individually to the control components. The phase characteristic proceeds along the path ^ap . Here, the phase characteristic is first modulated into a wave by a digital-to-analog converter 18 and a synthesizer 20 (in a particularly preferred embodiment, which is a voltage controlled oscillator). The synthesizer 20 provides an output wave composed of phase information. This output wave has a constant envelope. That is, although the amplitude does not change, it has the phase characteristic of the original input wave, proceeds to the driver 24, and then proceeds to the driver lines a ^p 1 to a ^p 7. The waves split in the driver line are then supplied to current sources 25a-25g and act to potentially drive the current sources 25a-25g, as further described below. In other embodiments, other sources of other wave characteristics can be used, ie, in addition to phase characteristics.

  Note that in this embodiment, transistors can be used as current sources 25a-25g. Furthermore, in other embodiments, one or more appropriately segmented transistors can be used as current sources 25a-25g. Current sources 25a-25g should not be configured to behave similarly to voltage sources, for example, by saturating transistors that interfere with the desired current combination of the sources.

The path a ^m (consisting of the control component lines a ^m 1 to a ^m 7 as described above) terminates in the control components 22a to 22g. In particularly preferred embodiments, these are switching transistors, preferably current sources, but as will be described further below, in other embodiments other sources of other wave characteristics may have other regulation schemes. As well as can be used. The control components 22a-g are switched by the bits of the digital word output from the amplitude component and are therefore regulated by the digital word output from the amplitude component. When a bit is "1" or "high", the corresponding control component is switched on, so that current is routed from the control component to the appropriate current source 25a-g along the deflection control lines 23a-g. Flowing into. As noted above, the length of a digital word can vary, so the number of bits, control components, control component lines, driver lines, deflection control lines, current sources, etc. can vary. May vary correspondingly in certain embodiments. Furthermore, they need not be one-to-one correspondence among digital word resolution, components, lines, and current sources in various embodiments.

  Current sources 25a-g receive current from the control component when the control component is on, and thus each current source is regulated according to that component. In a particularly preferred embodiment, as described further below, a suitable control component provides a deflection current to the current source, and thus the control component can be referred to as a deflection control circuit, Some of these can be referred to as deflection networks. In some embodiments, if desired, it may be desirable to use a switching network to statistically or dynamically assign one or more deflection control circuits to one or more current sources. There is.

  Returning now to the embodiment of FIG. 1, each current source can act as a potential current source and generate a current that is output to each of the current source lines 26a-g. Each current source may or may not act as a current source and therefore may or may not generate current because the current source is suitable to regulate the control component This is because it is regulated via a digital word value. Activation of any current source and generation of current from that current source relies on the appropriate bit value from the digital representation of the amplitude component that regulates the appropriate control component. It should be noted that the current source is a multiple current source function as an amplifier as described herein, rather than one or more amplifiers in the preferred embodiment. Indeed, amplification and / or attenuation can be considered as a function of those embodiments in the preferred embodiments, and thus amplifiers and / or attenuators are electrical components that amplify and / or attenuate or It can be considered a system.

  The combined current, ie the sum of all currents output from the current sources 25a-g, is the current source output. Thus, embodiments can act as attenuators and / or amplifiers. No further circuitry or components are required between the current sources to combine the currents from each current source and thus provide a useful output current. Thus, the combined current output on line 27 and denoted b can be used as desired, such as to drive a load, such as an amplifier, attenuator, etc.

  In a preferred embodiment, the current source varies in current output and size. This provides various weightings for the current potentially supplied by those current sources. For example, in one preferred embodiment, the first current source is twice the size of the next current source, the next current source is twice the size of the next current source, and so on. Continue to the source. The number of current sources can be matched to the number of bits in the digital control word, so the maximum current source is controlled by the MSB of the amplitude word and the next bit in the word controls the next maximum current source And so on until LSB sent to the minimum current source. Of course, as noted above, other embodiments may have different patterns for matching bits to current sources, including the use of switching networks. Furthermore, in a particularly preferred embodiment, a replicated current source (same size) is provided, as is a current source of varying size. In other embodiments, other wave characteristics can be provided to other current sources, thus regulating those sources.

  The current sources 25a-g comprise one or more HBT transistors in the preferred embodiment of FIG. Other transistors, such as FETs, can be used as well as other current sources. Other components such as variable gain amplifiers or attenuators can also be superimposed to reduce drive current to transistor segments, non-linear components along the amplification path, and the like.

  According to a preferred embodiment, the amplitude characteristic is preferably digitized. In one embodiment, the peak amplitude is set equal to the full scale of digitization (ie when all bits are set high). Alternatively, the peak amplitude can be set to anything other than the full scale of digitization (ie, larger or smaller). If the peak amplitude is less than full scale, an increase in gain is experienced because the average output power level is increased for a given power level of the phase modulated carrier signal.

  The use of the preferred embodiment can provide the ability to modify a wide range of band amplitudes in the associated transmitter, because over a relatively large envelope bandwidth due to the relatively low input capacitance. This is because linear amplification and / or attenuation is possible. Thus, embodiments can be used for cellular and other transmitters, as described below.

  As will be appreciated, any suitable type of current source, such as other transistor segments and / or formats, and other devices or methods may be used with any of the embodiments of the present invention, if desired. Is possible. In a preferred embodiment manufactured as a single integrated circuit, weighting can be achieved by providing segments with different semiconductor regions.

  Furthermore, preferred embodiments can include amplifiers that are specialized for specific input and output waves, etc., for example, cell phones such as CDMA, CDMA2000, W-CDMA, GSM, TDMA, etc. Various RF, microprocessors, microcontrollers and / or computer devices, and Bluetooth, 802.11a, -b, -g, radar, IxRTT, two-way radio, GPRS, computer and computer communication devices, PDAs and others It can be used in other wireless and wired devices such as handheld devices.

  Various embodiments can modify various parameters without departing from the spirit and scope of the present invention. For example, the length of a digital word can be longer or shorter in various embodiments, which can provide a somewhat accurate digitization of the wave. As another example, as described further above, the number of bits, control components, control component lines, driver lines, deflection control lines, current sources, etc. can be varied as desired. .

  Various types of system architectures can be used to construct embodiments of the present invention. Thus, one of ordinary skill in the art can implement embodiments of the present invention or various components and / or features thereof from hardware, software, or a combination of software and hardware. You will understand that it is possible. Embodiments or various components may also be provided for semiconductor devices, if desired, such as an integrated circuit or application specific integrated circuit composition. Some examples include silicon (Si), silicon germanium (SiGc), or gallium resin (GaAs) substrates.

  Although the present invention has been described in terms of exemplary embodiments, additional advantages and modifications will occur to those skilled in the art. Accordingly, the invention in its broadest aspects is not limited to the specific details shown and described herein. Modifications can be made without departing from the spirit and scope of the invention. Accordingly, the invention is not intended to be limited to the specific exemplary embodiments, but is to be construed as within the full spirit and scope of the appended claims and their equivalents.

It is a figure which shows preferable embodiment. FIG. 2 is a schematic diagram of the operation of the embodiment of FIG. 1.

Claims (56)

  An electromagnetic processing method comprising: regulating at least two independently controllable current sources with at least one wave characteristic, wherein the at least two independently controllable current sources are capable of generating a current.   The electromagnetic processing method according to claim 1, wherein the at least one wave characteristic is an amplitude characteristic.   The electromagnetic processing method according to claim 1, further comprising generating current through the at least two controllable current sources.   The electromagnetic processing method of claim 1, further comprising providing the at least one wave characteristic.   The electromagnetic processing method of claim 4, wherein providing the at least one wave characteristic comprises providing an amplitude characteristic.   The electromagnetic processing method according to claim 4, further comprising providing the at least one wave characteristic via a converter.   The electromagnetic processing method according to claim 4, further comprising providing the at least one wave characteristic via a pole converter.   The electromagnetic processing method according to claim 4, further comprising providing the at least one wave characteristic via a filter.   The electromagnetic processing method according to claim 4, further comprising providing the at least one wave characteristic via a digital-analog converter. Regulating at least two independently controllable current sources with at least one wave characteristic;
Providing said at least one wave characteristic to a second current source, said second current source being capable of generating a current, and upon generating the current, at least one of said at least two independently controllable current sources The electromagnetic processing method according to claim 1, further comprising regulating   The electromagnetic processing method according to claim 10, wherein the at least one wave characteristic is an amplitude characteristic. The at least one wave characteristic comprises a first wave characteristic and a second wave characteristic;
The electromagnetic processing method according to claim 1, wherein the first wave characteristic and the second wave characteristic are provided to the at least two independently controllable current sources.   The electromagnetic processing method according to claim 12, wherein the first wave characteristic is an amplitude characteristic.   The electromagnetic processing method according to claim 12, wherein the second wave characteristic is a phase characteristic.   The electromagnetic processing method according to claim 12, further comprising providing the first wave characteristic and the second wave characteristic synchronously.   The electromagnetic processing method according to claim 12, further comprising providing the first wave characteristic and the second wave characteristic via a converter.   The electromagnetic processing method according to claim 12, further comprising providing the first wave characteristic and the second wave characteristic via a pole converter.   The electromagnetic processing method according to claim 12, further comprising providing the second wave characteristic through a filter.   The electromagnetic processing method according to claim 12, further comprising providing the second wave characteristic via a voltage controlled oscillator.   The electromagnetic processing method according to claim 12, further comprising providing the first wave characteristic and the second wave characteristic via a digital-analog converter. Provides amplitude and phase characteristics synchronously,
An electromagnetic processing method comprising supplying the amplitude characteristic and the phase characteristic to a transistor capable of generating a current with at least two independently controllable current sources.   The electromagnetic processing method according to claim 21, further comprising generating an electric current. Providing first wave characteristics,
A first source of wave characteristics is regulated by the first wave characteristics;
Providing a second source of wave characteristics;
A transistor capable of regulating the second source of wave characteristics with the first source of wave characteristics, wherein the second source of wave characteristics can generate current with two or more independently controllable current sources; An electromagnetic processing method comprising:   Means for regulating at least two independently controllable current sources with at least one wave characteristic, the at least two independently controllable current sources comprising means capable of generating a current Processing equipment.   The electromagnetic processing apparatus according to claim 24, wherein the at least one wave characteristic is an amplitude characteristic.   25. The electromagnetic processing apparatus of claim 24, wherein the at least two independently controllable current sources generate current.   25. The electromagnetic processing apparatus of claim 24, further comprising means for providing the at least one wave characteristic.   28. The electromagnetic processing apparatus of claim 27, wherein the means for providing the at least one wave characteristic further comprises means for providing an amplitude characteristic.   28. The electromagnetic processing apparatus of claim 27, wherein the means for providing the at least one wave characteristic further comprises a transducer.   28. The electromagnetic processing device of claim 27, wherein the means for providing the at least one wave characteristic further comprises a pole converter.   28. The electromagnetic processing device of claim 27, wherein the means for providing the at least one wave characteristic further comprises a filter.   28. The electromagnetic processing device of claim 27, wherein the means for providing the at least one wave characteristic further comprises a digital to analog converter.   Means for providing said at least one wave characteristic to a second current source, said second current source being capable of generating a current, and as soon as it generates a current, said at least two independently controllable currents The electromagnetic processing apparatus according to claim 24, further comprising means for regulating at least one of the sources.   34. The electromagnetic processing apparatus according to claim 33, wherein the at least one wave characteristic is an amplitude characteristic. The at least one wave characteristic comprises a first wave characteristic and a second wave characteristic;
25. The electromagnetic processing apparatus of claim 24, further comprising means for providing the second wave characteristic to the at least two independently controllable current sources.   36. The electromagnetic processing apparatus according to claim 35, wherein the first wave characteristic is an amplitude characteristic.   36. The electromagnetic processing apparatus according to claim 35, wherein the second wave characteristic is a phase characteristic.   36. The electromagnetic processing apparatus according to claim 35, further comprising means for synchronously providing the first wave characteristic and the second wave characteristic.   36. The electromagnetic processing apparatus of claim 35, wherein the means for providing the first wave characteristic and the second wave characteristic further comprises a converter.   36. The electromagnetic processing apparatus of claim 35, wherein the means for providing the first wave characteristic and the second wave characteristic further comprises a pole converter.   36. The electromagnetic processing device of claim 35, wherein the means for providing the first wave characteristic and the second wave characteristic further comprises a digital to analog converter.   36. The electromagnetic processing device of claim 35, wherein the means for providing a first wave characteristic comprises a filter.   36. The electromagnetic processing apparatus of claim 35, wherein the means for providing a second wave characteristic further comprises a voltage controlled oscillator. A digital-to-analog converter and a polar converter for providing amplitude and phase characteristics synchronously;
An electromagnetic processing apparatus comprising: a transistor capable of generating a current with at least two independently controllable current sources for receiving the amplitude characteristic and the phase characteristic.   45. The electromagnetic processing apparatus of claim 44, wherein the transistor generates a current. Means for providing a first wave characteristic;
Means for regulating a first source of wave characteristics with the first wave characteristics;
Means for providing a second source of wave characteristics;
A means for regulating the second source of wave characteristics with the first source of wave characteristics, wherein the second source of wave characteristics generates an electromagnetic wave with two or more independently controllable current sources. An electromagnetic processing apparatus comprising: means for providing a transistor capable of performing the same. A converter that provides amplitude and phase characteristics synchronously;
An integrated circuit for electromagnetic processing, comprising: a transistor capable of generating a current with at least two independently controllable current sources for receiving the amplitude characteristic and the phase characteristic. Regulate the control components according to the amplitude characteristics of the wave,
An electromagnetic processing method, wherein two or more independently controllable transistor segments are regulated according to the control component, and the independently controllable transistor segments can generate a current.   The electromagnetic processing method according to claim 48, further comprising generating an electric current. Regulate multiple control components according to the amplitude characteristics of the wave,
An electromagnetic processing method comprising: regulating a plurality of independently controllable transistor segments according to the plurality of control components; wherein the plurality of independently controllable transistor segments can generate a current.   51. The electromagnetic processing method according to claim 50, further comprising generating an electric current.   An electromagnetic processing apparatus, comprising: means for regulating a plurality of independently controllable transistor segments according to a wave amplitude characteristic, wherein the transistor segments are capable of generating a predetermined current.   53. The electromagnetic processing apparatus of claim 52, wherein the means for regulating transistor segments according to wave amplitude characteristics comprises a control component regulated according to the wave amplitude characteristics.   54. The electromagnetic processing apparatus of claim 53, wherein the control component comprises a transistor.   Electromagnetic processing comprising: means for regulating a plurality of independently controllable transistor segments according to wave amplitude characteristics, wherein the plurality of independently controllable transistor segments comprise means capable of generating a predetermined current Integrated circuit.   56. The integrated circuit for electromagnetic processing according to claim 55, wherein said means for regulating transistor segments according to wave amplitude characteristics comprises a control component regulated according to said wave amplitude characteristics.

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