Automated Proofreading Report  

Document Name/Date: 36-000 US Final Specification.docx
Generated on November 24, 2020, 12:09 PM
Matter ID: N/A
Stats: Abstract: 252/150

Claim Text and Tree

Claim tree and searchable claim table are shown below (without amended deletions).
Claim Tree Claim Text
Color legend for claim types: Method , Apparatus, Composition, Article, Means For, Product, Jepson.
Only show independent claims
Indep. Claim

Reference part names/numbers in the specification

This tab shows part numbers and names identified in the specification and drawings/claims (if available). Frequency of each part name is shown in square brackets (if more than 1). Click "Show Help" for the list of additional operations.

Only show problems
Part Number Part Name in the Specification Appears in Figures? Appears in Claims? Errors?
1equation [2]
4
2element from figures
4
3element from figures
4
100tester module [5]
network
tester nodule
test device
1Yes
110controller [5]
1
120RF tuner
frequency RF tuner
1Yes
130detector [2]
1
140display [2]
1
200system
channel
method
2Yes
210channel selection block
2
212digital channel measurement block [4]
2
214channel plan [2]
2
216channel measurement block [4]
2
218evaluation block [7]
2
220configurable limit
2
222device specification database
2
224result
susceptibility result
2Yes
300method [4]
3
310channel selection block
3
312digital channel measurement block [4]
3
314channel plan [2]
3
316channel measurement block [3]
3
318evaluation block [4]
3
320threshold
3
322device specification database [2]
3
324corresponding result
3
326tilt calculator [4]
3
328tilt compensator [2]
3
330tilt reference
3
400thing
exemplary plot
plot
NoYes
412powers
analog signal powers
4Yes
414analog signal powers
powers
4Yes
416analog signal powers
powers
4Yes
418powers [2]
analog signal powers
4Yes
420analog signal powers
powers
4Yes
422powers
analog signal powers
4Yes
424analog signal powers
powers
4Yes
426analog signal powers
powers
4Yes
428powers [2]
analog signal powers
4Yes
430analog signal powers
powers
4Yes
432powers
analog signal powers
4Yes
434powers
analog signal powers
4Yes
436powers
analog signal powers
4Yes
438analog signal powers
4
500method [3]
reference numeral
NoYes
510block
thing
NoYes
512function block [2]
NoYes
514function block [2]
NoYes
516function block [2]
NoYes
518function block [3]
thing
NoYes
520function block [2]
NoYes
522function block [2]
NoYes
524end block
NoYes
542thing
NoYes
543thing
NoYes
560things [2]
NoYes
561things [2]
NoYes
562things
NoYes
563things
NoYes
810thing
NoYes
818thing
NoYes

Reference part names/numbers in figures

This tab shows any issues associated with figures. Click "Show Help" for the list of additional operations.
Figures Table Figures
 Only show problems Pages: 12345All Pages
Page/Fig #s Issues Description and Part Numbers Errors?
Page/Fig #s Issues Description and Part Numbers Errors?
1 [Fig 1] Page size of 10 x7.5 inches is neither letter (8.5 x 11) nor A4 (see 37 CFR 1.84(f)).

Figure 1 is a schematic diagram of an intermodulation testing device in accordance with an exemplary embodiment of the present disclosure.

Parts List:
100  tester module
110  controller
120  RF tuner
130  detector
140  display
No
2 [Fig 2] Page size of 10 x7.5 inches is neither letter (8.5 x 11) nor A4 (see 37 CFR 1.84(f)).

Fonts may be too small: 8.04pt, 9pt.

Figure 2, a method executable by the controller 110 of Figure 1 is indicated generally by the channel 200.

Parts List:
200  system
210  channel selection block
212  digital channel measurement block
214  channel plan
216  channel measurement block
218  evaluation block
220  configurable limit
222  device specification database
224  result
No
3 [Fig 3] Page size of 10 x7.5 inches is neither letter (8.5 x 11) nor A4 (see 37 CFR 1.84(f)).

Fonts may be too small: 9pt, 8.04pt.

Figure 3 is a functional diagrams of a controller with tilt compensation for the testing device of Figure 1 in accordance with an exemplary embodiment of the present disclosure.

Parts List:
300  method
310  channel selection block
312  digital channel measurement block
314  channel plan
316  channel measurement block
318  evaluation block
320  threshold
322  device specification database
324  corresponding result
326  tilt calculator
328  tilt compensator
330  tilt reference
No
4 [Fig 4] Page size of 10 x7.5 inches is neither letter (8.5 x 11) nor A4 (see 37 CFR 1.84(f)).

Figure 4 is a graphical diagram of measured powers of analog channels in accordance with an exemplary embodiment of the present disclosure.

Parts List:
1  equation
412  powers
414  analog signal powers
416  analog signal powers
418  powers
420  analog signal powers
422  powers
424  analog signal powers
426  analog signal powers
428  powers
430  analog signal powers
432  powers
434  powers
436  powers
438  analog signal powers
No
5 [N/A] Could not detect figure number in the drawings.

No

This tab shows all limiting expiressing or 'patent profanities' identified in the specification. Click on terms to search the specification.
Problematic Term Issue

This tab shows all possible acronyms (i.e., terms with capitalized letters) identified in the document. Click on terms to search the specification.

Only show problems
Acronym Definition in Specification Identified Issues

This tab shows DOCX conversion issues and warnings identified in the document.
DOCX Conversion Issues Suggested Fix

Specification Text

This tab shows specification text (excluding claims section). Search the table using the smart search box (only table entries with search hits will be shown) or print/export the table in CSV format.
CATV DIGITAL RECEIVER INTERMODULATION SUSCEPTIBILITY TESTER MODULE
BACKGROUND
The present invention relates to cable television (CATV) receivers. More particularly, the present invention relates to a method and apparatus for measuring the susceptibility to intermodulation distortion of digital CATV receivers.
Intermodulation distortion generally occurs in a digital receiver, such as a cable modem or set-top box, when the total power of all signals input to the receiver is too high relative to the power of the digital signal desired to be demodulated. However, if the relative power level of the desired digital channel could be increased, the receiver might attenuate all incoming signals and substantially stop the intermodulation distortion from occurring.
When intermodulation distortion occurs, the receiver must decode errors that are not caused by impairments within the digital channel. Existing test instruments always measure the bit error rate caused by impairments within a digital channel, but not those caused by intermodulation distortions generated within the receiver, such as a cable modem, set-top box, or other consumer-grade receiver. Test instrument receivers may be capable of rejecting relatively high signal amplitude levels that fall outside of the particular frequency range of the digital channel being measured. On the other hand, the receivers used in consumer-grade equipment are typically not so capable. Thus, the test instruments are unable to measure or accurately estimate bit errors caused by intermodulation distortion at a consumer-grade receiver. Therefore, such test instruments will generally fail to report problems that cause impairments in consumer-grade equipment.
Unfortunately, the difference in amplitude levels between the lowest and highest frequencies carried on a cable is typically not a constant value. A coaxial cable, for example, attenuates higher frequencies. This effect is known as tilt. In order to compensate for attenuation, amplifiers are used to boost the overall signal power. Equalizers may be used in conjunction with the amplifiers so that the net signal boost is greater for higher frequencies, thereby reducing the tilt.
SUMMARY
These and other issues are addressed by a method and apparatus for testing susceptibility of a receiver to intermodulation distortion of a digital channel. Exemplary embodiments are provided.
An exemplary method of the present disclosure includes selecting a first digital channel from a plurality of channels in a composite signal, determining a first power measurement from said first digital channel, determining a total power measurement from at least one other channel in said composite signal, and determining susceptibility of said first digital channel to intermodulation distortion by comparing said first power measurement and said total power measurement with intermodulation distortion characteristics of said receiver.
Another exemplary method is provided wherein said receiver comprises a cable television (CATV) receiver. Another exemplary method is provided wherein said first digital channel and said at least one other channel comprise video channels. Yet another exemplary method is provided wherein at least one of said first power measurement or said total power measurement is determined at an input of said receiver.
Another exemplary method is provided, further comprising determining a level-versus-frequency tilt of said composite signal. Another exemplary method is provided wherein said level-versus-frequency tilt of said composite signal is determined at an input of said receiver. Yet another exemplary method is provided, further comprising compensating for a differing signal tilt when performing at least one of said first or total power measurements at a location different from a location of said receiver by utilizing said level-versus-frequency tilt.
Another exemplary method is provided wherein said at least one other channel in said composite signal comprises at least one analog channel. Yet another exemplary method is provided wherein said at least one other channel in said composite signal comprises a plurality of analog channels.
channel measurement block 216 channel plan 214
Another exemplary method is provided, further comprising computing a relative power ratio between said first power measurement and said total power measurement. Yet another exemplary method is provided, further comprising using said relative power ratio to predict the likelihood that other devices receiving said first digital channel will be impaired by internal intermodulation distortions.
Another exemplary method is provided, further comprising generating a tilt line for a plurality of channels in said composite signal to use as a reference power. Yet another exemplary method is provided, further comprising outputting a susceptibility result for said first digital channel in accordance with said reference power so that a same test device will give a same susceptibility result at different points in a network having different tilts.
An exemplary intermodulation test device is provided for testing susceptibility of a receiver to intermodulation distortion of a digital channel, the device comprising a tuner for selecting a first digital channel from a plurality of channels in a composite signal, a detector in signal communication with the tuner for determining a first power measurement from said first digital channel and determining a total power measurement from at least one other channel in said composite signal, and a controller in signal communication with the detector for determining susceptibility of said first digital channel to intermodulation distortion by comparing said first power measurement and said total power measurement with intermodulation distortion characteristics of said receiver.
Another exemplary device is provided, further comprising a display in signal communication with the controller for outputting a result indicative of the determined susceptibility of said first digital channel to intermodulation distortion. Yet another exemplary method is provided, the controller comprising a channel selection unit, a channel plan unit, a digital channel measurement unit in signal communication with the channel selection unit and the channel plan unit, another channel measurement unit in signal communication with the channel plan unit, an evaluation unit in signal communication with the digital channel measurement unit, and a results unit in signal communication with the evaluation unit.
Another exemplary device is provided wherein the evaluation unit is further in signal communication with the other channel measurement unit. Another exemplary device is provided, further comprising a configurable limit unit in signal communication with the evaluation unit. Yet another exemplary device is provided, further comprising a device specification database in signal communication with the evaluation unit.
Another exemplary device is provided, further comprising a tilt calculator in signal communication with the other channel measurement unit, a tilt reference unit in signal communication with the tilt calculator, and a tilt compensator in signal communication with each of the digital channel measurement unit and the other channel measurement unit, wherein the evaluation unit is in signal communication with both the digital channel measurement unit and the tilt compensator.
The present disclosure will be further understood from the following description of exemplary embodiments, which is to be read in connection with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
The present disclosure will be described in greater detail with reference to the accompanying drawings, which represent exemplary embodiments thereof, in which:
Figure 1 is a schematic diagram of an intermodulation testing device in accordance with an exemplary embodiment of the present disclosure;
Figure 2 is a functional diagram of a controller for the testing device of Figure 1 in accordance with an exemplary embodiment of the present disclosure;
Figure 3 is a functional diagrams of a controller with tilt compensation for the testing device of Figure 1 in accordance with an exemplary embodiment of the present disclosure;
Figure 4 is a graphical diagram of measured powers of analog channels in accordance with an exemplary embodiment of the present disclosure; and
Figure 5 is a flow diagram for a method of intermodulation susceptibility testing device in accordance with an exemplary embodiment of the present disclosure.
DETAILED DESCRIPTION
The present disclosure provides a method and apparatus for testing the likelihood that a receiver will be impaired by internal intermodulation (IM) distortions as a result of the power distribution across the channels within the received signal. Preferred embodiments measure the signals present on a cable rather than those present within a digital receiver. The IM distortion itself is generated within a digital receiver when adverse signal conditions are present. Such adverse signal conditions may include power relative to the desired signal at frequencies above and/or below the frequency band containing the desired signal, for example.
An exemplary embodiment measures the susceptibilities of cable television (CATV) digital receivers to IM distortion. Exemplary embodiments operate by analyzing signal levels to be input to the receivers, either at the receivers or at known or estimated cable lengths upstream from the receivers. Embodiments may compare the highest analog channel amplitude to the lowest digital channel amplitude, compensate for the inherent tilt of typical coaxial cables, evaluate a user-selected channel, or reference tilt and power.
A system embodiment measures and reports the signal conditions on a CATV network that can cause intermodulation distortions to occur in consumer-grade digital receivers, enabling technicians to identify and correct the problem. The presently disclosed testing device is capable of measuring the tilt at the point of measurement and compensating for the tilt when it computes the susceptibility to intermodulation distortion. The device may be used to evaluate a single digital channel or scan all digital channels and measure the one with the greatest susceptibility to intermodulation distortion, for example.
As shown in Figure 1, an intermodulation testing device is indicated generally by the network 100. The tester module 100 includes a controller 110, a frequency (RF) tuner 120 connected to the controller, a detector 130 connected to both the controller and the tuner, and a display 140 connected to the controller. The RF tuner 120 is capable of tuning to any channel being broadcast on the CATV network. The detector 130 may include one or more appropriate detectors for measuring the power of analog and/or digital TV channels. The controller 110 may include non-volatile memory for storing both an operating program and configuration data. The display 140 may be as simple as an indicator light or as elaborate as a touch screen for configuring the device, selecting channels, and reporting measurement progress and results.
Turning to Figure 2, a method executable by the controller 110 of Figure 1 is indicated generally by the channel 200. The method 200 includes a channel selection block 210, which passes control to a digital channel measurement block 212. The digital channel measurement block receives a channel plan 214, which contains a description of the channels being transmitted on the cable, including frequency and modulation type. The thing 542 also includes a thing 543 therein for receiving the thing 518, 818 of the thing 510, 810..  The thing 400 may also include a pair of other things or things 562, 563..  The things may be things, that is, things having ends with shapes which can engage with the things 560, 561..The digital channel measurement block 212 measures the power of a selected digital channel. For example, one method of measuring the digital channel power is known in the art as Digicheck. Another less accurate method is to measure the power at the center frequency and add a bandwidth compensation factor based on the ratio of digital channel bandwidth to measurement bandwidth. The digital channel measurement block 212 may perform the power measurement periodically in order to update the display with current results.
Another channel measurement block 216 also receives the channel plan 214, and measures the power of all or a subset of the channels being transmitted. The other channel measurement block 216 may measure all the channels, or just those that could substantially contribute to intermodulation distortion. Such other measured channels could be the video carriers of the analog TV channels, for example, since they normally have the highest power. The other channel measurement block 216 may perform only one measurement for each channel, measure all of them periodically, or select a small number with the highest power and measure them periodically in order to update the display with current results.
An evaluation block 218 is connected to both the digital channel measurement block 212, for receiving measured channel power and frequency, and to the other channel measurement block 216, for receiving measured power versus frequency. The evaluation block 218 compares the power of the digital channel being tested to the power of the other channels and determines whether a device receiving the digital channel is susceptible to intermodulation distortions.
Different types of evaluations are possible in the evaluation block 218. In a first example, the evaluation block 218 may subtract the digital channel power from the highest of the other channels’ measured powers. If this result is over a threshold value or configurable limit 220, the channel is indicated as susceptible. The degree of susceptibility may be indicated by the amount that the difference exceeds the threshold. In a second example, the evaluation block 218 may sum the measured powers of the other channels to get a total integrated power, and then subtract the digital channel power from this sum.
As in the first example, the evaluation block compares the value to a threshold to evaluate the susceptibility to intermodulation distortions. In a third example, the evaluation block 218 may consider the capability of a tuner to reject off-frequency signals as a function of frequency or difference in frequency between the digital channel being received and the frequency of the other signal. Here, the evaluation block 218 sums the amount by which the power of any channel other than the digital channel being evaluated exceeds the device’s rejection capability. The sum of these is defined herein as the “total overload power”. As in the first example, the evaluation block compares this value to a threshold to evaluate the susceptibility to intermodulation distortions.
In an alternate embodiment, the method may measure the powers of only those channels for which sums and differences of harmonic frequencies of two or three channels falls within the frequency band of the first digital channel. Here, composite second order (CSO) distortion is the sum or difference of two signals or their harmonics, and composite triple beat (CTB) distortion is the sum and/or difference of three signals or their harmonics.
The controller 110 or tester module 100 of Figure 1 may further evaluate the susceptibility of a single digital channel selected by the user. The tester module may also scan all digital channels and report the susceptibility of each. The tester module may report which channel is most susceptible and the particular susceptibility of only that channel. The TCP tester module may display or otherwise output a susceptibility report or result 224, which may be a pass/fail indicator and/or the degree of susceptibility, displayed either numerically or graphically. The tester module may evaluate susceptibility compared to a reference specification from a device specification database 222, which database may provide overload power versus frequency. The specification may be configurable. The tester module 100 may further contain a database of the susceptibility characteristics of various receiver devices. A user of the tester module could select a device from the database, and the tester module would report its susceptibility.
The susceptibility result 224 of this exemplary embodiment may be valid for devices connected at or near the same location as the tester module. The signal may have a different tilt at other locations.
Turning now to Figure 3, another method executable by the controller 110 of Figure 1 is indicated generally by the method 300. The method 300 is similar to the system 200; so duplicate description shall be omitted. The method 300 includes extra functional blocks to perform tilt compensation, such as to measure susceptibility at other locations distant from the location of the tester nodule 100.
The method 300 includes a channel selection block 310, which passes control to a digital channel measurement block 312. The digital channel measurement block receives a channel plan 314. The digital channel measurement block 312 measures the power of a selected digital channel. Another channel measurement block 316 also receives the channel plan 314, and measures the power of at least some of the other channels being transmitted.
A tilt calculator 326 is connected to the other channel measurement block 316, and provides a tilt reference 330. A tilt compensator 328 is connected to each of the digital channel measurement block 312, the other channel measurement block 316, and the tilt calculator 326 for receiving a current tilt value.
An evaluation block 318 is connected to both the digital channel measurement block 312 and the tilt compensator 328 for receiving compensated power of other channels. The evaluation block 318 may receive a limit specification or threshold 320 and/or information from a device specification database 322. The evaluation block 318 compares the power and/or compensated power of the digital channel being tested to the compensated powers of the other channels, determines whether a device receiving the digital channel is susceptible to intermodulation distortions, and outputs a corresponding result 324.
As shown in Figure 4, a plot of measured powers of analog TV channels is generally indicated. The plot 400 includes measured analog signal powers 412, 414, 416, 418, 420, 422, 424, 426, 428, 430, 432, 434, 436 and 438, each at a different carrier frequency. Here, a first frequency span S1 includes the measured powers 412, 414, 416 and 418. A second frequency span S2 includes the measured powers 418, 420, 422, 424, 426 and 428; and a third frequency span S3 includes the measured powers 428, 430, 432, 434 and 436. The tilt calculator 326 of Figure 3 may use these measured powers to compute a slope of a tilt line. A tilt line is a straight line intersecting the measured levels of two of the highest channels such that all other channels have less than or equal to the power at that frequency on the tilt line.
In the exemplary plot 400, tilt lines L1, L2 and L3 are present. If two or more possible tilt lines are found, as here, the one covering the widest frequency span is used. From the three possible tilt lines, L2 is selected over L1 and L3 because it has the widest frequency span S2. If two or more tilt lines are found having equal frequency spans, the one with less tilt is used. The tilt calculator 326 outputs the slope of the tilt line, but need not calculate nor output the y-intercept.
A user may assume that the signal has no tilt at the point that subscriber equipment is connected. Alternatively, the user may use the device to measure the actual tilt at the subscriber location. If the actual tilt is used, the device may store it as a reference tilt. If known, the reference tilt value may also be entered into the device without performing a tilt measurement.
When tilt compensation is used, the device first measures the tilt. It uses the difference between the current tilt and the reference tilt to adjust the measured powers of all channels. The amount of adjustment is given by the equation:
tiltComp(freq) = (refTilt – currentTilt) * (freq – digFreq) (Equation 1)
In Equation 1, currentTilt is the measured tilt at the current location, refTilt is the tilt at the location of the subscriber’s receiver, freq is the frequency of the channel being adjusted, and digFreq is the frequency of the digital channel for which susceptibility is being evaluated. The adjustment is added to the measured value before passing it on to the evaluation block 318.
Turning to Figure 5, a method for assessing susceptibility of a CATV receiver to intermodulation distortion is indicated generally by the reference numeral 500. The method 500 includes a start block 510, which passes control to a function block 512. The function block 512 selects a first digital channel from a plurality of channels in a CATV signal, and passes control to a function block 514. The function block 514 determines a first power measurement of the first digital channel at the CATV receiver input, and passes control to a function block 516. The function block 516 determines a total power measurement from one or more of the other channels in the CATV signal at the CATV receiver input, and passes control to a function block 518. The function block 518, in turn, determines the susceptibility of the first digital channel to intermodulation distortion by comparing the first and total power measurements with known intermodulation distortion characteristics of the CATV receiver.
Optionally, the method 500 may further include a function block 520, which receives control from the function block 518 and determines a level-versus-frequency signal tilt at the CATV receiver input. In addition, the method 500 may further include a function block 522, which receives control from the function block 520 and uses the level-versus-frequency signal tilt measured at the CATV receiver input to compensate for the differing signal tilt when performing the signal power measurements at a location in the network other than at the original CATV receiver input. The function block 522 may then pass control to an end block 524.
The above and alternate embodiments provide a method and apparatus for measuring and analyzing the signals present at the input of a CATV digital receiver, and thereby determining its susceptibility to intermodulation (IM) distortion. The IM distortion results when the total power received across all digital and analog signal frequencies exceeds by a critical amount the strength of the selected digital signal being demodulated. Technicians can use this diagnostic tool to measure a single digital channel and/or scan all digital channels, and pursue appropriate corrective action for instances in which susceptibility to IM distortion is indicated. Embodiments may also use a level-versus-frequency signal tilt compensation feature, which enables a tester module 100 to evaluate a receiver connected at a different location in the network from that of the tester module.
Preferred embodiments of the test device 100 of Figure 1 may use a relative power ratio between the analog video channels and a digital channel in order to predict the likelihood that other devices receiving that digital channel will be impaired by internal intermodulations. Such other devices may be of different types, each having unique specifications stored in a device specification database 322, for example. A tester module 100 may further generate a tilt line for use as the reference power so that the same device will give the same results at different points in the network that have different tilts.
Although illustrative embodiments have been described herein with reference to the accompanying drawings, it is to be understood that the present disclosure is not limited to those precise embodiments, and that various other changes and modifications may be effected therein by those of ordinary skill in the pertinent art without departing from the scope or spirit of the present disclosure. All such changes and modifications are intended to be included within the scope of the present disclosure as set forth in the appended claims.
CLAIMS
ABSTRACT OF THE DISCLOSURE
A method and apparatus are provided for testing susceptibility of a receiver to intermodulation distortion of a digital channel, the method including selecting a first digital channel from channels in a composite signal, determining a first power measurement from the first digital channel, determining a total power measurement from other channels in the composite signal, and determining susceptibility of the first digital channel to intermodulation distortion by comparing the first power measurement and the total power measurement with intermodulation distortion characteristics of the receiver. A method and apparatus are provided for testing susceptibility of a receiver to intermodulation distortion of a digital channel, the method including selecting a first digital channel from channels in a composite signal, determining a first power measurement from the first digital channel, determining a. A method and apparatus are provided for testing susceptibility of a receiver to intermodulation distortion of a digital channel, the method including selecting a first digital channel from channels in a composite signal, determining a first power measurement from the first digital channel, determining a total power measurement from other channels in the composite signal, and determining susceptibility of the first digital channel to intermodulation distortion by comparing the first power measurement and the total power measurement with intermodulation distortion characteristics of the receiver total power measurement from other channels in the composite signal, and determining susceptibility of the first digital channel to intermodulation distortion by comparing the first power measurement and the total power measurement with intermodulation distortion characteristics of the receiver