Patent Abstract:
A digital signal processor transceiver uses a finite impulse response filter memory to construct a phase integrated angle at each clock cycle. The FIR filter memory is addressed by a multibit pattern and a time count which are used in conjunction to determine the address. Each data word of the FIR filter memory represents the sum of two tap points multiplied by their tap coefficients. Several of the most significant bits of the phase integrated angle are used to address look up tables for the signal&#39;s sine and cosine values. The address for the cosine look up table may further be phase compensated. Filter types other than a FIR filter may be used.

Full Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
   This application claims the benefit of U.S. Provisional Application No. 60/291,715, filed May 17, 2001, which is hereby incorporated by reference. 

   FIELD OF THE INVENTION 
   The present invention generally relates to the field of wireless data communications and, particularly, to digital signal processor transceiver in a wireless data communications device. 
   BACKGROUND OF THE INVENTION 
   Current digital signal processors, as well as other processes and components, in wireless communications devices rely on rechargeable or replaceable batteries for power. Extending the life of the battery is an important goal in the wireless communications industry. Although current devices are designed with power savings as a goal, further improvement in power conservation is an ongoing goal. 
   Another goal in wireless communications devices is to provide a device which is smaller in size and which provides a relatively great amount of functionality for its size and weight. Smaller and lighter devices place less of a burden on the user who transports them. Although this goal has been recognized in the design of current devices, further improvement also is an ongoing goal. 
   Therefore, it would be desirable to provide a digital signal processing method and device which uses fewer stages in processing and, thereby, conserves power. 
   SUMMARY OF THE INVENTION 
   Accordingly, the present invention is directed to a digital signal processor transceiver which more efficiently processes data to be transmitted from a wireless communications device. This is accomplished through a simple design that incorporates a filter such as a finite impulse response filter, phase integration, phase correction, and trigonometric value look up for sine and cosine values which form the informational signals. 
   In a first aspect of the present invention, a method of selecting a frequency in a digital signal processor includes the steps of inputting a data bit, determining a plurality of first values associated with the data bit and previously input data bits, successively adding the plurality of first values to a sum, and, on each successive adding of the plurality of first values to the sum, using a portion of the sum to provide an in-phase value and a quadrature value. The portion of the sum may be modified by a phase corrector and the modified sum may then be used to obtain a quadrature value. The method may be implemented in software, hardware, firmware, or a combination of any or all of these techniques. 
   The present invention offers a digital signal processor transceiver that has a simple and compact design low in cost to manufacture. The present invention requires fewer processing stages than the current devices and uses less power. For instance, current devices often use several stages of adders to provide and sum a tap value; in the present invention, a single stage is used. The present invention may be adapted for increased flexibility to provide for loadable tap points, loadable predistortion data, and loadable phase correction data. 
   In a particular embodiment, the present invention performs compact processing by using a 24 tap Gaussian finite impulse response filter. The 24 tap FIR filter may be used in a BLUETOOTH communications device in which the bandwidth-time (BT) product is 0.5. An accumulator implements phase integration for frequency modulation. A phase corrector may be used to correct any phase error in the divide by two quad generator employed in using the most significant bits of the accumulated phase angle to determine the in-phase and quadrature values of the information signal. Furthermore, a finite impulse response memory, such as a ROM, may be predistorted to compensate for imperfect integration and sin (x)/x error. 
   It is to be understood that both the forgoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention as claimed. The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate an embodiment of the invention and together with the general description, serve to explain the principles of the invention. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The numerous advantages of the present invention may be better understood by those skilled in the art by reference to the accompanying figures in which: 
       FIG. 1  illustrates a digital signal processor transceiver of the present invention; 
       FIG. 2  illustrates a method of the present invention for generating an integrated phase angle; 
       FIG. 3  illustrates a method of the present invention for generating the in-phase and quadrature components of the data signal; 
       FIG. 4  illustrates an exemplary graph of an output response from the digital signal processor transceiver of the present invention; and 
       FIG. 5  illustrates an exemplary graph of an output response from the digital signal processor transceiver of the present invention. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   Reference will now be made in detail to the presently preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. The present invention may be implemented as a digital signal processor vector modulator that converts baseband data to a modulated signal, such as a BLUETOOTH Gaussian Frequency Shift Keying (GFSK) modulated signal in which a data bit (or data bits) is represented by a shift in frequency. Other modulation techniques, such as Frequency Shift Keying (FSK) may be used. GFSK passes the baseband data through a Gaussian filter to make the data smoother so to limit its spectral width. 
   Referring generally now to  FIGS. 1 through 5 , exemplary embodiments of the present invention are shown. 
     FIG. 1  illustrates an embodiment of digital signal processor (DSP) transceiver  100  of the present invention. The DSP transceiver may include a shift register  10 , a counter  20 , a filter memory  30 , an adder  40 , a latch  50 , a phase corrector  70 , a sine memory  60 , and a cosine memory  80 . A clock signal DSPCLK and a data bit are inputs of the DSP. A sample clock, an in-phase value, and a quadrature value are outputs. The shift register receives a data bit from the radio baseband at the same rate that the counter rolls over. The counter is driven by the clock signal DSPCLK ( FIG. 1 ). 
   The DSP transceiver filters the baseband data to improve the spectral response of the information transmitted. Finite impulse response (FIR) filters may be used to implement any impulse response of a finite length. The coefficients may be static and may rely on a fixed channel transfer function. The coefficients may be dynamic and may require back channel data to ensure robust operation. Although FIR filters are discussed, the present invention may also be practiced with infinite impulse response (IIR) and other types of filters. Beside Gaussian filters, the present invention may be practiced with Butterworth, Chebyshev, elliptic, Bessel-Thompson, raised-cosine, pole-zero, polynomial, and other filters. 
   The front end of the DSP transceiver consists of an address generating circuit for data storage retrieval. The address generating circuit may include a delay circuit, a latch, and a counter. In a particular example, as shown in  FIG. 1 , the delay circuit and the latch are represented by a shift register  10 . The three bit pattern of the shift register may serve to tune to a particular frequency (a three bit pattern allows for eight selections). Instead of a three bit pattern, a one bit pattern, a two bit pattern, a four bit pattern, or a pattern of a higher number of bits may be used. With a four bit pattern, sixteen selections are possible. In the particular example, the address of the finite impulse response read only memory (FIR ROM) is made up of the three bits of data from the shift register and four bits from the counter  20 . The address generating circuit may be implemented in software or hardware. Software offers greater options in making changes to the process. Hardware provides faster processing. A combination of hardware and software may be used. The counter in this particular embodiment counts from 0 to 11, but may be set to count fewer times or a greater number of times. For instance, the counter may count from 0 to 15 or from 0 to 23. In the particular example of  FIG. 1 , the FIR ROM is addressed twelve times for every time a bit is shifted into the shift register. When the counter has reached its maximum count value, it may be reinitialized by circuit logic or the like. 
   An example of the address generating process implemented through software code, using MathCad.C, is provided below to illustrate a particular example of generating the address: 
   Module dsp_tx_sample ( 
   clk, 
   reset, 
   btxd, 
   sample, 
   ); 
   input clk; 
   input reset; 
   input btxd; 
   output brclk; 
   output [6:0] sample; 
   reg [3:0] phase; 
   reg [2:0] btxd hist; 
   reg last_btxd; 
   always @ (posedge elk) 
   if (reset) begin 
   last_btxd &lt;=#1 btxd; 
   btxd_hist &lt;=#1 0; 
   phase &lt;=#1 0; 
   end 
   \\ else if ((last_btxd !=btxd)||(phase ==4′d11)) begin 
   else if (phase ==4′d11) begin 
   btxd_hist &lt;=#1 (btxd_hist [1:0], btxd); 
   last_btxd &lt;=#1 btxd; 
   phase &lt;=#1 0; 
   end 
   else phase &lt;=#1 phase +1; 
   wire [6:0] sample ={btxd_hist, phase}; 
   wire brclk =(phase ==4′d11); 
   endmodule 
   The address is used to retrieve stored phase angle values which represent the tap points of a desired filter response. A filter response may be constructed from a number of samples, i.e., the stored phase angle values. The memory may be loadable to permit recalibration of the filter values. This may be needed because of aging of the devices, a change in location of the device, or a change in environment. 
   In the particular example of  FIG. 1 , data describing a filter is placed in storage. The storage may be accomplished by a variety of means, including a software routine or a volatile or non-volatile memory. A Gaussian finite impulse response filter offers a symmetrical relationship to reduce the number of process steps per data bit. It also offers flexibility in design and a stable output. Preprocessing of the filter characteristics at a receiver may be used to derive the appropriate FIR filter coefficients which are incorporated in the FIR ROM. The derivation of the FIR filter coefficients may be accomplished by an analysis of the inverse transfer function of the transceiver. Because corresponding coefficients or tap weights are symmetric for a Gaussian type response, each memory word may contain the sum of the products of two tap points and their corresponding coefficients. Thus, the number of computations per data bit may be reduced by half. The embedded coefficients may be determined by a tap weight algorithm and may be updated periodically or as needed to reasonably track changes in the RF propagation characteristics. In particular, a 24 tap Gaussian finite impulse response filter may be used in a BLUETOOTH communications device in which the bandwidth-time (BT) product is 0.5. 
   Each tap of the filter memory may be integrated using an accumulator to provide a phase angle through phase integration. The accumulator may be an arithmetic logic unit, a software adding routing, etc. Phase integration is useful because it permits a simpler design and superior performance by maintaining the same harmonic structure throughout. The accumulated phase angle ramps up for each successive DSPCLK. In the particular example, one output cycle of the transceiver occurs when the fourteen bit latch rolls over. Fourteen bits are used to provide adequate resolution of the angle. Only the eight most significant bits are actually used to determine the sine and cosine of the accumulated phase angle. The six least significant bits help to maintain overall accuracy in the angle and to provide for the compensation of distortion. The fastest rate that the fourteen bit latch may roll over is slightly more than every 2.7 bits input to the shift register  10 . The slowest rate of change for the fourteen bit latch is zero, providing that the FIR ROM repeatedly reads out a zero word for each and every bit pattern and for every time the counter increments. If the bit input rate of the shift register is 1 MHz, then the maximum frequency of the transceiver is slightly under 372 KHz, corresponding to a roll over of the latch value. The present invention is not limited to a fourteen bit representation of the accumulated phase angle. A thirteen bit, a fifteen bit, or other sized latch may be used. 
   The accumulated phase angle is further processed to define an RF signal represented by the sine value and the cosine value. These component values are usually designated as an in-phase (I) component and a quadrature (Q) component. These components form informational components which modulate the carrier signal. 
   In the particular example, the eight most significant bits of the integrated phase correspond to an accumulated phase angle. Depending upon the particular requirements of the system, a fewer or greater number of bits may be used. Using fewer bits, such as six or seven, conserves on resources. Using a greater number of bits, such as nine, ten, or sixteen, provides for a higher resolution. 
   In the particular example, the most significant bits of the accumulated phase angle are further processed for further phase compensation. The processing may be accomplished through dedicated circuitry or through software code. A look up table may be used to provide correction values. The correction values may be loadable to the phase corrector. This permits the user to recalibrate the transceiver as needed. For example, if the user transports the transceiver to another location within a building or outside. In the particular example, the phase correction is performed before the cosine values are determined. This processing may, alternatively, be performed for both sine and cosine processes or solely for the sine determination process. 
   The sine and cosine of the accumulated phase angle are determined. Their sine and cosine values may be calculated through a software routine, may be determined through hardware computation, may be found through a memory such as a read only memory or an electrically erasable programmable read only memory, may be found through a look up table, etc. The sine value represents the in-phase value of the RF signal and the cosine value represents the quadrature value of the RF signal. In the particular example, the sine and cosine values may be six bit values. 
   An example of software code for determining the sine and cosine values is provided: 
   \\ This file is generated by math.c 
   module dsp_sincos_rom (sin_addr, sin, cos_addr, cos); 
   input [7:0] sin_addr, cos_addr; 
   output [5:0] sin, cos; 
   reg [5:0] sin, cos; 
   always @ (sin_addr) begin 
   case (sin_addr) 
   \\256 entries of the form 8′hxx: sin =6′hyy 
   \\where xx is an 8 bit hex number and yy is a 6 bit hex number 
   endcase 
   end 
   always @ (cos_addr) begin 
   case (cos_addr) 
   \\256 entries of the form 8′hxx: cos =6′hyy 
   \\where xx is an 8 bit hex number and yy is a 6 bit hex number 
   endcase 
   end 
   endmodule 
   The in-phase and quadrature components are further processed to generate the RF signal. They may be immediately converted to analog form by a digital to analog converter. 
     FIG. 2  illustrates the process steps in determining the accumulated phase angle from the baseband data. A count and a sum are initialized, as per COUNT/SUM step  210 . A data bit is input, as per INPUT step  220 . As the count is below the maximum value, a tap value is selected from storage in response to the data bit directly or as a pattern of bits which define a storage address, as per SELECT step  250 . The tap value is added or accumulated to the sum, as per ADD step  260 . The count is incremented, as per RESET step  280 . If a reset command has issued, the process returns to INITIALIZATION step  210 . Otherwise, the process goes to COUNT/MAX step  230  where a determination is made as to whether the count has exceeded a maximum set value. This maximum set value may be hardwired or may be set through a software or firmware loading operation (or the like). If the count exceed a maximum value, the count is reinitialized  240 . 
     FIG. 3  illustrates the next stage of the process in which the most significant bits of the sum, representing the accumulated phase angle, are used to determine the in-phase and quadrature components of the data signal. The most significant bits are extracted from the sum, as per EXTRACT step  300 . This may be achieved through a software masking operation, through a latch, or by simply hardwiring the designated lines to the appropriate circuitry (or the like). The sine value corresponding to the most significant bits, as per FIND step  310 , is found. The sine value is the in-phase value of the data signal. The same set of most significant bits may be optionally processed for making a phase correction, as per CORRECT step  320 . The phase corrected most significant bits may then be used to determine the cosine value (i.e., the quadrature value). 
     FIGS. 4 and 5  illustrate graphs of a sample output from an exemplary DSP transceiver of the present invention. 
   It is believed that the present invention and many of its attendant advantages will be understood by the forgoing description. It is also believed that it will be apparent that various changes may be made in the form, construction and arrangement of the components thereof without departing from the scope and spirit of the invention or without sacrificing all of its material advantages. The form herein before described being merely an explanatory embodiment thereof. It is the intention of the following claims to encompass and include such changes.

Technology Classification (CPC): 7