One aspect of the technology implements the multiplying element and DAC as a differential current mode device.
One aspect of the technology uses weighted addition deferred after multiplication of the DAC/Multiplier combination, allowing substantially equal DAC weights in columns of the differential current multiplier independent of bit position.
One aspect of the technology uses non-radix2 in the addition deferred after multiplication, operating the DAC as a partially segmented DAC, with correspondingly higher accuracy.
One aspect of the technology rotates or otherwise scrambles the bit allocation for elements in a segmented DAC, such as cases where the DAC is a segmented DAC and the scrambling is on the equally weighted segments.
One aspect of the technology implements the DAC by selectively enabling duplicates of the devices on the input port of the multiplier.
One aspect of the technology modifies the effective length of the DAC dependent upon the particular coefficient value by selecting neither of the duplicates of the devices on the input port of the multiplier, consequently enhancing the signal to noise ratio of the CSF and reducing its current.
One aspect of the technology uses one, some, or all the techniques described herein in a complex filter (one operating on complex numerical quantities) where the subtraction and addition is in the current domain, and two resistor networks rather than the expected four, are used to complete the weighted addition.
An improved tuner such as for television relies on a Channel Select Filter (CSF) to define channel selection via frequency shaping, after the coarse tuning of a preceding Radio Frequency Digital Sampling Mixer (RFDSM). The quadrature output channels of the RFDSM operate at a variable internal intermediate frequency (IF), such as in a range of 8 to 14.5 MHz. The CSF is a complex semi-analog finite impulse response (FIR) filter. The complex filter operates upon signals represented as complex numbers, expressed as an in-phase signal and a quadrature signal (I and Q). The complex filter includes multiple FIR filters of taps (e.g., 160 taps) utilizing a digital-to-analog converter (DAC) at each tap position to generate the coefficient value. A set of samples of the signal are passed down a delay line and each is multiplied by the coefficient and summed to a single output. Four such filters are arranged to process the complex quadrature signals from the RFDSM. Consequently the CSF can select either the positive or the negative output frequency, suppressing the unwanted one of the pair.
The coefficients in the CSF are digital words, each independently adjustable. Because of this ability to change the coefficients, aspects of the CSF to be adjusted, such as bandwidth, steepness of band-edge, stop band rejection, or other frequency response shape. In response to a user selected channel and a subsequent adjustment of the RFDSM around a new internal IF frequency, the coefficients the CSF coefficients adjust to define a channel selection mask. Calibration is not required, as the CSF is precisely related to the clock and the filter shape achievable with the coefficients of the CSF are mathematically exact.
Additional details are described as follows. The CSF has an array of sample-and-hold circuits associated with a multiplier core and a digital-to-analog converter (DAC), e.g. 12 bit DAC. In the complex filter configuration, four banks of multiplier/DAC elements are arranged, e.g. four banks of 160 multiplier/DAC elements totaling 640 such multiplier/DAC elements. In the CSF FIR filter, the sample is analog and the multiplicand is the DAC output value. The rate of passage of the signal down the array of samplers is determined by the clock. Therefore the frequency shaping and the overall response characteristic are directly related to the clock with no error due to the value of on-chip components. Consequently, the band edge, for example, is precise.
The filter implements any shape with precision, limited by the 160 elements, per the Parks-McClellan algorithm sometimes referred to as the Remez Exchange algorithm. Because the preceding RFDSM is restricted to certain frequencies, the CSF constantly adjusts its bandpass position to center around the downmixed required signal. A ROM of precalculated coefficient values is provided on chip and a small DSP engine selects and loads the appropriate coefficient set given the user's selected receive frequency. In another embodiment, the CSF coefficients are loaded from the Inter-Integrated Circuit (I2C), subject to time constraints of loading.
Because the CSF is a sampled data system which samples the input signals (I and Q) from the RFDSM, an anti-aliasing filter (AAF) prevents the alias signal in continuous time, without affecting the band shaping. In one embodiment, the AAF is implemented with on-chip metal finger capacitors and poly-silicon resistors and is sufficiently precise to meet requirements without calibration.
Semi Analog Finite Impulse Response Filter
A Semi Analog Finite Impulse Response Filter (FIR) is a transversal filter implemented with coefficient values and samples, one of which is essentially digital and one of which is analog. Typically, the sample is analog and the coefficient is digital. The multiplication and summation to output is done in the analog domain, requiring that the digital coefficient value is rendered into an analog signal by a DAC, as shown in
An issue with the semi-analog FIR filter of
The following will focus on the implementation of a semi analog FIR filter with rotating coefficients and implementation of the DAC and multiplier.
The relation of output change to input change is shown in the graph of
If the source IS was replaced by a DAC, and if the input parameter V(C,D) was the SHA output, such a simple multiplier may be viable as the DAC/Multiplier combination in a semi-analog FIR filter. Although the CSF can this simple multiplying core, our technology addresses a number of problems, not least of which are that the IS parameter is uni-polar, and the accuracy of this multiplier structure would be a limitation.
Multiplication in Differential Current Mode
The circuit of
The circuit of
It is difficult to use the circuit of
Summing with Different Weights in the Output of One Coefficient DAC
To extend this to more than one bit, rather than varying the current source, replicas of the circuit with fixed current source are added, as in
The SHA input is shared, but the Bit is separate. The outputs add in a resistor network that applies a variable gain to the output node. The right hand block (controlled by Bit2/Bit2b) contributes an amount to the output that is two times that contribution of the middle block (controlled by Bit1/Bit1b), determined by the value of the resistors R9 and R10 in relation to R5 and R6. The left hand block (controlled by Bit0/Bit0b) contributes half again of the middle bit. The resistors make an R-2R ladder network with terminating resistor R11. Consequently, we have a three bit equivalent DAC.
Although we have a DAC, there is no variable current source and the multiplier core devices (M5/6, M7/10 and M13/16) work at the same constant current. This ensures good linearity. If the currents were to differ, the multiplication constant would change. To further clarify the operation at this point we can explicitly write the descriptive equation:
where Bn={−1,+1}. Clearly we have a 3 bit DAC multiplying the SHA.
Summing with Different Weights in the Output of a Complete FIR Filter
This DAC is to be used in the CSF, i.e. in a semi-analog FIR filter.
Columns of similarly weighted multiplier cores are connected together. It is not required to provide a separate resistor network for each one.
Using Non-Radix 2 to Provide Enhanced Accuracy and Segmented Operation
Up to this point the limitation of accuracy of the equivalent DAC is due to the resistor mismatch. If these resistors match to 0.1% then the overall DAC is correspondingly 0.1% accurate. Addition of more multiplier cells can improve this by converting the DAC to a partially so-called “segmented” DAC architecture. For example, three multiplier cores can add to make one compound core that has four possible operating conditions, as shown in
Three of the multiplier sections add their output currents together into one resistor load network. That network then connects to the next compound group, not with a weight of (½), but with a weight of (¼). The effect of this is that two bits are available in each group of three cores and the resistors then provide the remaining relative weights. The burden on the resistor matching is therefore somewhat reduced and the DAC will have a high accuracy. Two bits are available from the three core cells, because the possible states are as shown in the following table, namely that there are four possible outputs −3, −1, +1, +3, the −1 and +1 states occurring multiple times.
The redundancy in the codes is exploited in the programming sequence. For example, the three codes that represent −1 are each chosen in turn when needed. This differs from a typical decision to choose say, L=0,M=0,R=1 as the code for −1 all the time and causes the mismatch that may exist between Left Middle and Right cells to be scrambled.
The choice of three sections per bit is exemplary. More sections can be chosen, and further that the segmentation need not continue to the LSB—by the time we reach the LSB bit positions the inherent matching is more than adequate to meet requirements. Various embodiments do not segment one or more of the lower order bits. In summary, operation with other than radix two gives two benefits: the resistor need not match the equivalent DAC accuracy, hence system accuracy is improved; and secondly redundancies in coding may be exploited to “scramble” and matching error within a segment group.
Selectively Enabling Duplicate Input Devices
The fixed current source that replaced the DAC in various embodiments has been shown as a symbol, not exposing the actual transistors that make up the current source. Some embodiments use a current source as follows.
Modification to the Effective DAC Length
The duplication of input pairs and removal of reversing arrangement has advantages described in the following.
Each of these 212 coefficients is expressed as a DAC value in the 212 DACs that make up the semi-analog FIR filter. These DAC values will rotate as disclosed. Most of the DAC values are small. In this example, there are 36 values that are less than 10. The design can be optimized, such that when fewer than 12 bits are needed, which is quite frequently, some resource may be saved.
The table of
A 12 bit radix-4 segmented current mode DAC has six two bit sections. It is made up of six groups of three elements. (Two groups of three elements are shown in the schematic on
For example, this DAC creates the equivalent of +999. It does so by encoding (from MSB to LSB) the sequence (1, −1, 3, 3, −3, 3). This can be verified by forming the summation 1*1024−1*256+3*64+3*16−3*4+3=999. The code applied to the segmented DAC sections would then be 110,100,111,111,000,111 (as appear in the table accompanying the description of
In another example, the DAC representing −27 does so by encoding (−1, 3, 3, 3, −3, 1), which is confirmed by forming the summation −1*1024+3*256+3*64+3*16−3*4+1=−27.
The DAC size can be reduced. To create the number −27, we first encoded −1024, the bulk of which canceled out by adding first 768 (i.e. 3*256) then 192 (i.e. 3*64), finally leaving −27. Various embodiments dispense with adding the current and noise associated with the encoding of −1024, 768 and 192 since these values largely cancel out one another. In some specific example of encoding −27, a segmented DACs of only three groups of three is sufficient. It can encode −27 as (−1, −3, 1) as confirmed by the summation −1*16−3*4+1=−27. Accordingly, various embodiments simplify the circuitry, reduce current, and limit noise. In the differential current mode DAC, the quantity zero is represented as two currents that are the same: the current in the left branch being made equal to the current in the right branch. The difference in current is zero, and hence the two equal currents represent zero signal. But two currents are never equal, and have noise associated with them. This noise does not reduce to zero, and in fact adds root-sum-square (i.e. it increases). Consequently, an improvement is made not by the cancellation of large quantities, but by the removal of the segmented DAC currents of the higher order bits when not needed.
Some DAC embodiments cannot create an even number; all numbers of such DACs are odd. (e.g., in the range −4095 to +4095 in steps of 2, with 4095 such numbers with this DAC being very nearly 12 bits.)
We encode DAC values into the electronic devices when we use the duplicate input device method as shown in
The bits are shown in the table of
In the encoding whenever a Bit is set, the corresponding Bitb is unset and so forth. We are connecting either the input pair that connects one way to the output bus, or the input pair that connects the opposite way to the output bus. Consider the table of bit states of
Again we have created the same sample output values (in the # column) as in the last example. Note that, for example, Bit10 and Bit10b are now both zero at the same time (as are Bit11/Bit11b and Bit12/Bit12b). By using the ‘duplicate input device’ method, certain sections of the DAC can be shut off. This shutting off is possible when the DAC number is such that MSB sections are not needed. Alternative embodiments achieve this. A third pair of devices may have been added to the ‘reversing switch’ arrangement. But this is a convenient embodiment to shut off the DAC sections that are not needed to implement small numerical values, i.e. small coefficient values in our example. The consequence is that no current flows in certain multiplying elements and current consumption is less, so noise is less.
Unlike in these simplified example embodiments where a weighted resistor network is shown associated with each DAC, in a complete filter embodiment, the resistor network occurs one time at the very ‘top’ of the filter. Consequently, as the coefficients rotate and certain of them implement this “off state” in certain multipliers, the current does not change in the weighting resistors. There is no “common mode” glitch or similar effect due to the current turning on and off; the same (lower than before) current always flows.
Use of One Weighted Resistor Network Per Pair of FIRs in a Complex Filter
A ‘complex filter’ in this context refers to a filter designed to operate upon data represented as complex numbers. These kinds of filter are common in communication systems. A complex filter is desirable in certain circumstances due to its ability to distinguish positive and negative frequencies. A complex filter is made from real filters as in
While the present invention is disclosed by reference to the preferred embodiments and examples detailed above, it is to be understood that these examples are intended in an illustrative rather than in a limiting sense. It is contemplated that modifications and combinations will readily occur to those skilled in the art, which modifications and combinations will be within the spirit of the invention and the scope of the following claims.
This application is a divisional of U.S. patent application Ser. No. 13/145,748, which is a U.S. National Stage of International PCT Application No. PCT/US2010/22266, filed on 27 Jan. 2010, which claims the benefit of U.S. Provisional Application No. 61/147,826, filed on 28 Jan. 2009, each of which are hereby incorporated by reference herein.
Number | Name | Date | Kind |
---|---|---|---|
3831016 | Nathan | Aug 1974 | A |
4000401 | Quinn, Jr. | Dec 1976 | A |
5877974 | Can | Mar 1999 | A |
5886916 | Muraoka | Mar 1999 | A |
7702716 | Rosener | Apr 2010 | B2 |
Number | Date | Country |
---|---|---|
1019980027536 | Jul 1998 | KR |
1020030069515 | Aug 2003 | KR |
Number | Date | Country | |
---|---|---|---|
20150222249 A1 | Aug 2015 | US |
Number | Date | Country | |
---|---|---|---|
61147826 | Jan 2009 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13145748 | US | |
Child | 14619940 | US |