UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD. MAXLINEAR, INC. Petitioner

UNITED STATES PATENT AND TRADEMARK OFFICE BEFORE THE PATENT TRIAL AND APPEAL BOARD MAXLINEAR, INC. Petitioner v. CRESTA TECHNOLOGY CORPORATION Patent Owner CASE: IPR2015-00594 Patent 7,265,792 Title: Television Receiver for Digital and Analog Television Signals PETITION FOR INTER PARTES REVIEW OF U.S. PATENT NO. 7,265,792 UNDER 35 U.S.C. 312 AND 37 C.F.R. 42.104 Mail Stop PATENT BOARD U.S. Patent Trial & Trademark Office P.O. Box 1450 Alexandria, VA 22313-1450

TABLE OF CONTENTS I. COMPLIANCE WITH FORMAL REQUIREMENTS... 1 A. Grounds for Standing (37 C.F.R. 42.104(a))... 1 B. Real Parties-In-Interest (37 C.F.R. 42.8(b)(1))... 1 C. Related Matters (37 C.F.R. 42.8(b)(2))... 1 D. Counsel and Service Information (37 C.F.R. 42.8(b)(3)-(4))... 2 E. Statement of Precise Relief Requested... 4 II. REASONABLE LIKELIHOOD TO PREVAIL... 4 III. IDENTIFICATION OF CHALLENGE... 4 A. Prior Art Publications... 4 B. Brief Statement of Grounds for Challenge... 6 1. Grounds are Not Redundant of the Original Prosecution... 8 2. Grounds are Not Redundant of Other Petitions for IPR... 9 3. The Grounds in the IPR2015-00626 Petition... 10 IV. INVALIDITY OF THE 792 PATENT... 11 A. Introduction... 11 B. Prosecution History of the 792 Patent... 12 C. Person of Ordinary Skill in the Art... 15 V. CLAIM CONSTRUCTION... 15 A. Summary of Claim Terms Construed... 16 B. RF signal... 16 C. format... 17 D. video and audio baseband signals... 17 ii

E. signal processor... 18 VI. DETAILED EXPLANATIONS OF THE CHALLENGES... 19 A. Ground 1: Claims 1, 2, 4, 5, 11 and 24-29 are anticipated by Favrat... 20 B. Ground 2: Claim 3 is obvious over Favrat in view of Arambepola... 29 C. Ground 3: Claim 6 is obvious over Favrat in view of Yang... 30 D. Ground 4: Claim 7, 8, 9 and 12 are obvious over Favrat in view of Wilkie... 32 E. Ground 5: Claim 10 is obvious over Favrat in view of Vorenkamp... 35 F. Ground 6: Claims 13-15 and 18 is obvious over Favrat in view of Oku... 37 G. Ground 7: Claims 16, 17 and 19 are obvious over Favrat in view of Oku... 44 H. Ground 8: Claims 20-23 are obvious over Favrat in view of Oku and further in view of Eglit and Wilkie... 46 VI. CONCLUSION... 52 iii

EXHIBIT LIST Exhibit 1101 Exhibit 1102 U.S. Patent No. 7,265,792 ( the 792 patent ). Complaint in Cresta Technology Corporation v. Maxlinear, Inc. et al., Case No. 1:14-cv-00079-RGA before the United States District Court for the District of Delaware (January 21, 2014) ( Complaint ). Exhibit 1103 Complaint in ITC Investigation No. 377-TA-910 (June 12, 2014) ( ITC Amended Complaint ). Exhibit 1104 Exhibit 1105 Exhibit 1106 Exhibit 1107 Exhibit 1108 Exhibit 1109 Exhibit 1110 Favrat et al., U.S. Patent No. 7,075,585, titled Broadband Receiver having a Multistandard Channel Filter, filed September 6, 2002 ( Favrat ). Yang, U.S. Patent No. 5,663,768, titled Multi-Television Broadcasting Signal Receiving Apparatus and Control Method Thereof, filed June 6, 1995 ( Yang ). Wilkie, U.S. Patent No. 5,526,017, titled Analog Image Signal Processor for a Multimedia System, filed October 26, 1993 ( Wilkie ). Vorenkamp et al., U.S. Patent No. 7,106,388, titled Digital IF Demodulator for Video Applications, filed December 15, 2000 ( Vorenkamp ). Oku et al., U.S. Patent No. 6,310,654, titled Decoder Device and Receiver Using the Same, filed February 2, 1999 ( Oku ). Gray et al., U.S. Patent No. 4,872,054, titled Video Interface for Capturing an Incoming Video Signal and Reformatting the Video Signal, filed June 30, 1988 ( Gray ). Eglit et al., U.S. Patent No. 5,642,139, titled PCMCIA Video Card, filed April 29, 1994 ( Eglit ). 1

Exhibit 1111 Exhibit 1112 IEEE 100: The Authoritative Dictionary of IEEE Standards Terms, Seventh Edition Excerpts of the prosecution file history of the 792 patent. Exhibit 1114 J. Mitola, The Software Radio Architecture, IEEE Communications Magazine, May 1995 ( Mitola 95 ). Exhibit 1115 Exhibit 1116 Exhibit 1117 Exhibit 1118 Exhibit 1119 Exhibit 1120 Exhibit 1121 Exhibit 1122 J. Mitola, Software Radio Architecture: A Mathematical Perspective, IEEE Journal on Selected Areas in Communications, vol. 17, no. 4, April 1999 ( Mitola 99 ). Software Radio Architecture: Object-oriented Approaches to Wireless Systems Engineering, Joseph Mitola III, Wiley, January 2000 ( Mitola 00 ). D. Efstathiou, Recent Developments in Enabling Technologies for Software Defined Radio, IEEE Communications Magazine, vol. 1, pp. 112 117, August 1999 ( Efstathiou 99 ). D. Efstathiou, SoftCellTM: A Multi-carrier Chip-set for Software Definable Radio Base-stations, IEEE Global Communications Conference, vol. 1, pp. 172 176, 2000 ( Efstathiou 00 ). J. Razavilar, F. Rashid-Farrokhi, and K. J. Liu, Software Radio Architecture With Smart Antennas: A Tutorial on Algorithms and Complexity, IEEE Journal on Selected Areas in Communications, vol. 17, no. 4, pp. 662 676, April 1999 ( Razavilar 99 ). Micronas Introduces First All CMOS Intermediate Frequency (IF) Chip To Handle Analog and Digital Broadcast Signals (0020), November 21, 2000 ( Micronas 00 ). STV0399 Front-End Single Chip for Digital Satellite Broadcasting, STMicroelectronics, 2001 ( STM 01 ). W. Boie, Broadcast Receiver Adapted for Analog and Digital 2

Signals, 1996 European Patent application EP 0696854, 1996 ( Thomson ). Exhibit 1123 W. Zhang, T. Misko, and J. Woodburn, Digital Implementation of Multi-Channel Demodulators, U.S. Patent 6,704,372, issued March 9, 2004 (filed Sep. 18, 2001) ( Zhang 01 ). Exhibit 1124 Exhibit 1125 Exhibit 1126 Exhibit 1127 Exhibit 1128 Exhibit 1129 Exhibit 1130 Exhibit 1131 Exhibit 1132 Software Radio Technology and Service, Editor: E. Del Re, Springer, 2001 ( DelRe 01 ). A Look at Software Radio: Are They Fact or Fiction, Electronic Design, December 1, 1998 ( ED 98 ). R. Coy, C. Smith, and P. Smith, HF-Band Radio Receiver Design Based on Digital Signal Processing, Electronics & Communication Engineering Journal, pp. 83 90, April 1992 ( Coy 92 ). RF Microelectronics, Behzad Razavi, Publisher: Prentice Hall, 1997 ( Razavi 97 ). The Design of CMOS Radio-Frequency Integrated Circuits, Thomas H. Lee, Publisher: Cambridge University Press, 1998 (excerpt, Lee 98 ). E. Colin, L. Naviner, P. Loumeau, and J. Naviner, Trade-Off Between Antialiasing Filter and Analog-To-Digital Converters Specifications in Homodyne Radio Frequency Receivers, in IEEE VTC, pp. 2351 2354, 2001 ( Colin 01 ). Signals and Systems, A. Oppenheim, Prentice Hall, Second Edition, 1997 ( Oppenheim 97 ). Digital Signal Processing A Computer-Based Approach, Sanjit Mitra, McGraw Hill, Second Edition, 2001 ( Mitra 01 ). CMOS Wireless Transceiver Design, Jan Crols and Michiel Steyaert, Kluwer Academic Publishers, 1997 (excerpt, Crols 97 ). 3

Exhibit 1133 Exhibit 1134 Exhibit 1135 Exhibit 1136 Exhibit 1137 Exhibit 1138 Exhibit 1139 C. Strolle and S. Jaffe, Multiple Modulation Format Television Signal Reception System, US Patent 6,005,640, December 1999 ( Strolle 99 ). C. Robbins, R. Friedman, and M. Fazili, Digital Signal Processor for Multi-Standard Television, US Patent 6,147,713, November 2000 ( Robbins 00 ). D. Ehrhardt and T. Benkner, wrote a paper published in the August 1993 issue of the IEEE Transactions on Consumer Electronics ( Ehrhardt 93 ). H. Yoshida and H. Tsurumi, Software Radio Technology and Service. ( Yoshida 01 ). A. Balaban, M. Low, and E. Fox, Receiver for Analog and Digital Television Signals, US Patent 6,369,857, April 2002 ( Balaban ). R. Van De Plassche, A. Bruekers, G. Giellis, Multi-Standard Reception, US Patent 6,643,502, November 2003 ( VDP ). Arambepola et al., U.S. Patent No. 7,280,616, titled Optimizing a Filter Bandwidth in a Digital Receiver, filed October 27, 2003, which claims priority to British Application 0225598.2, with a priority date of November 2, 2002 4

Petitioner hereby requests that the United States Patent and Trademark Office proceed with an inter partes review of claims 1 29 of U.S. Patent No. 7,265,792 ( the 792 patent ) (Ex. 1101). I. COMPLIANCE WITH FORMAL REQUIREMENTS A. Grounds for Standing (37 C.F.R. 42.104(a)) In accordance with 37 C.F.R. 42.104(a), Petitioner certifies that the 792 patent is available for inter partes review. Petitioner further certifies that Petitioner is not barred or estopped from requesting an inter partes review challenging the 792 patent on the grounds identified in this Petition. B. Real Parties-In-Interest (37 C.F.R. 42.8(b)(1)) MaxLinear, Inc. ( Petitioner ) and Cresta Technology Corporation ( Patent Owner or CrestaTech ) are the real parties-in-interest in this matter. C. Related Matters (37 C.F.R. 42.8(b)(2)) Patent Owner has filed two actions against Petitioner in which Patent Owner alleges that Petitioner infringes the 585 patent: Cresta Technology Corporation v. Maxlinear, Inc. et al., Case No. 1:14-cv-00079-RGA, filed on January 21, 2014, in the United States District Court for the District of Delaware (Complaint, Ex. 1102); and Investigation No. 337-TA-910, filed on January 28, 2014, in the International Trade Commission ( ITC ) (ITC Amended Complaint, Ex. 1103). In both cases, Patent Owner also sued certain of Petitioner s customers (Sharp and VIZIO, Inc.). 1

In addition to these lawsuits, co-defendant/co-respondent, Silicon Laboratories, Inc. has also filed the following petitions seeking inter partes review of the Cresta patents asserted in the ITC Complaint: Proceeding No. Patent at Issue Filing Date Petitioner 2014-00728 7,075,585 May 5, 2014 Silicon Laboratories 2014-00809 7,265,792 May 23, 2014 Silicon Laboratories 2015-00615 7,075,585 January 23, 2015 Silicon Laboratories 2015-00626 7,265,792 January 26, 2015 Silicon Laboratories 2015-00591 7,075,585 January 28, 2015 MaxLinear 2015-00592 7,075,585 January 28, 2015 MaxLinear 2015-00593 7,265,792 January 28, 2015 MaxLinear 2015-00594 Petition 7,265,792 January 28, 2015 MaxLinear On October 24, 2014, the Board instituted review of claims 1, 2 and 4 17 of the 792 patent in IPR2014-00809. D. Counsel and Service Information (37 C.F.R. 42.8(b)(3)-(4)) Address all e-mails and telephone calls to lead and back up counsel (each associated with the above Customer Number), listed below: 2

Lead Counsel Name: Thomas J. Wimbiscus (Reg. No. 36,059) (twimbiscus@mcandrews-ip.com) Direct: 312-775-8109 Back-Up Counsel Name: Christopher C. Winslade (Reg. No. 36,308) (cwinslade@mcandrews-ip.com) Direct: 312-775-8108 Name: Gregory C. Schodde (Reg. No. 36,668) (gschodde@mcandrews-ip.com) Direct: 312-775-8117 Name: Scott P. McBride (Reg. No. 42,853) (smcbride@mcandrews-ip.com) Direct: 312-775-8131 Name: Ronald H. Spuhler (Reg. No. 52,245) (rspuhler@mcandrews-ip.com) Direct: 312-775-8210 Wayne H. Bradley (Reg. No. 39,916) (wbradley@mcandrews-ip.com) Direct: 312-775-8187 Address all communications to: Thomas J. Wimbiscus Christopher C. Winslade Gregory C. Schodde Scott P. McBride Ronald H. Spuhler Wayne H. Bradley MCANDREWS HELD & MALLOY 500 W. Madison, 34 th Flr. Chicago, IL 60661 312-775-8000 3

Please direct all correspondence regarding this proceeding to the lead counsel at the address listed above. Patent Owner also consents to electronic service by e-mail to MXL-IPR@mcandrews-ip.com. The Patent Trial and Appeal Board is hereby authorized to charge any fees associated with this proceeding to Deposit Account 13-0017 (Customer ID 23446). E. Statement of Precise Relief Requested In accordance with 37 C.F.R. 42.22, Petitioner respectfully requests cancellation of claims 1 29 of the 792 patent. II. REASONABLE LIKELIHOOD TO PREVAIL This Petition, in accordance with 35 U.S.C. 314(a), establishes a reasonable likelihood that Petitioner will prevail with respect to at least one of the claims challenged in this petition because the Petition provides evidence and supporting reasoning showing that all of the elements of each of claims 1 29 of the 792 patent are unpatentable over the prior art. III. IDENTIFICATION OF CHALLENGE A. Prior Art Publications Petitioner relies on the following prior art publications: 1. Favrat et al., U.S. Patent No. 7,075,585, titled Broadband Receiver having a Multistandard Channel Filter, filed September 6, 2002 (Exhibit 1104) ( Favrat ). Favrat claims priority to Provisional U.S. Patent Application 4

60/322,548 filed September 17, 2001. Favrat is prior art at least under 35 U.S.C. 102(e) (pre-aia). 2. Yang, U.S. Patent No. 5,663,768, titled Multi-Television Broadcasting Signal Receiving Apparatus and Control Method Thereof, filed June 6, 1995 (Exhibit 1105) ( Yang ). Yang claims priority to Korean Patent Application 94-12940, with a priority date of June 9, 1994. Yang is prior art at least under 35 U.S.C. 102(e) (pre-aia). 3. Wilkie, U.S. Patent No. 5,526,017, titled Analog Image Signal Processor for a Multimedia System, filed October 26, 1993 (Exhibit 1106) ( Wilkie ). Wilkie claims priority to U.S. Patent Application No. 625,734 filed December 11, 1990, abandoned. Wilkie is prior art at least under 35 U.S.C. 102(e) (pre-aia). 4. Vorenkamp et al., U.S. Patent No. 7,106,388, titled Digital IF Demodulator for Video Applications, filed December 15, 2000 (Exhibit 1107) ( Vorenkamp ). Vorenkamp claims priority to 60/171,199, filed on December 15, 1999. Vorenkamp is prior art at least under 35 U.S.C. 102(e) (pre-aia). 5. Oku et al., U.S. Patent No. 6,310,654, titled Decoder Device and Receiver Using the Same, filed February 2, 1999 (Exhibit 1108) ( Oku ). Oku claims priority to Japan Application 10-022916, with a priority date of 5

February 4, 1998. Oku is prior art at least under 35 U.S.C. 102(e) (pre- AIA). 6. Gray et al., U.S. Patent No. 4,872,054, titled Video Interface for Capturing an Incoming Video Signal and Reformatting the Video Signal, filed June 30, 1988 (Exhibit 1109) ( Gray ). Gray is prior art at least under 35 U.S.C. 102(e) (pre-aia). 7. Eglit et al., U.S. Patent No. 5,642,139, titled PCMCIA Video Card, filed April 29, 1994 (Exhibit 1110) ( Eglit ). Eglit is prior art at least under 35 U.S.C. 102(e) (pre-aia). 8. Arambepola et al., U.S. Patent No. 7,280,616, titled Optimizing a Filter Bandwidth in a Digital Receiver, filed October 27, 2003 (Exhibit 1139) ( Arambepola ). Arambepola claims priority to British Application 0225598.2, with a priority date of November 2, 2002. Arambepola is prior art at least under 35 U.S.C. 102(e) (pre-aia). B. Brief Statement of Grounds for Challenge Petitioner challenges claims 1 29 ( the challenged claims ) of the 792 patent. Petitioner requests IPR of Claims 1-29 on the grounds set forth in the table below, and requests that they be found unpatentable and be canceled. An explanation of unpatentability under the statutory grounds identified below is provided in the detailed description that follows, indicating where each element 6

can be found in the cited prior art, and the relevance of that prior art. Additional explanation and support for each ground of rejection is set forth in the Declaration of Dr. Hashemi. (Ex. 1112). Grounds 792 Patent Basis for Rejection Ground 1 1, 2, 4, 5, 11 and 24-29 Anticipated under 102(e) by Favrat and Obvious under 35 U.S.C. 103(a) over Favrat Ground 2 3 Obvious under 35 U.S.C. 103(a) over Favrat in view of Arambepola Ground 3 6 Obvious under 35 U.S.C. 103(a) over Favrat in view of Yang Ground 4 7-9 and 12 Obvious under 35 U.S.C. 103(a) over Favrat in view Wilkie Ground 5 10 Obvious under 35 U.S.C. 103(a) over Favrat in view of Vorenkamp Ground 6 13-15 and 18 Obvious under 35 U.S.C. 103(a) over Favrat in view of Oku 7

Ground 7 16, 17 and 19 Obvious under 35 U.S.C. 103(a) over Favrat in view of Oku and further in view of Gray Ground 8 20-23 Obvious under 35 U.S.C. 103(a) over Favrat in view of Oku and further in view of Eglit and Wilkie 1. Grounds are Not Redundant of the Original Prosecution The application for Favrat, the application for Oku, and Grey were admitted in the 792 patent as being prior art. The Favrat application was relied upon by the Examiner to initially reject claims 1 4, 11, 12 and 29 (as issued) of the 792 patent during original prosecution of the 792 patent. In particular, the Examiner identified all features of claims 1 4, 11, 12 and 29 in the Favrat application except for the limitation requiring a plurality of FIR filters in independent claim 1. The Favrat application and Oku application were relied upon by the Examiner to initially reject claims 5, 10, 13 and 14. The Favrat application, the Oku application, and Gray were relied upon by the Examiner to initially reject claims 6 9, 15, and 18 29. Despite allowance by the Examiner based on the plurality of FIR filters feature of claim 1, this feature appeared (almost verbatim) in the Favrat 8

application. Grounds 1-8 in the Petition correct this oversight. 2. Grounds are Not Redundant of Other Petitions for IPR The grounds in the IPR2014-00809 petition are: Ground 1: Claims 1, 2, 4, 10, 11, and 26 are invalid under 35 U.S.C. 103 as obvious over Thomson (EP 0696854) in view of Harris (A Digital Tuner for Wideband Receivers). Ground 2: Claims 1, 2, 4, 10, 11, and 26 are invalid under 35 U.S.C. 103 as obvious over Thomson in view of TI App Note. Ground 3: Claim 3 is invalid under 35 U.S.C. 103 as obvious over Thomson and Harris in further view of Gunter (USP 4,782,385) or, in the alternative, Thomson and TI App Note in further view of Gunter. Ground 4: Claims 5 and 6 are invalid under 35 U.S.C. 103 as obvious over Thomson and Harris in further view of Cirrus Logic (NTSC/PAL digital video encoder) or, in the alternative, Thomson and TI App Note in further view of Cirrus Logic. Ground 5: Claims 7 and 12 are invalid under 35 U.S.C. 103 as obvious over Thomson and Harris in further view of Kerth (USP 6,804,497) or, in the alternative, Thomson and TI App Note in further view of Kerth. Ground 6: Claims 13 17 are invalid under 35 U.S.C. 103 as obvious over Thomson and Harris in further view of Oku and Kerth or, in the 9

alternative, Thomson and TI App Note in further view of Oku and Kerth. Ground 7: Claims 8 and 9 are invalid under 35 U.S.C. 103 as obvious over Thomson and Harris in further view of Kerth and Cirrus Logic or, in the alternative, Thomson and TI App Note in further view of Kerth and Cirrus Logic. Ground 8: Claims 26 and 27 are invalid under 35 U.S.C. 103 as obvious over Thomson and Harris in further view of Balaban (USP 6,369,857) or, in the alternative Thomson and TI App Note in further view of Balaban. Ground 9: Claims 1 is invalid under 35 U.S.C. 102 as anticipated by Patel (USP 6,124,898). 3. The Grounds in the IPR2015-00626 Petition Ground 1: Claim 29 is invalid under 35 U.S.C. 103 as obvious over Thomson in view of Harris. Ground 2: Claims 24 and 25 are invalid under 35 U.S.C. 103 as obvious over Thomson and Harris in view of Grumman. Ground 3: Claims 26 and 28 are invalid under 35 U.S.C. 103 as obvious over Thomson and Harris in view of Zenith. Ground 4: Claim 27 is invalid under 35 U.S.C. 103 as obvious over Thomson and Harris in view of Zenith and Birleson. Ground 5: Claims 18 and 19 are invalid under 35 U.S.C. 103 as obvious 10

over Thomson and Harris in further view of Oku, Ericsson, and Nguyen. Grounds 1-8 in the Petition comprise claims 20-23, which were not included in IPR2014-00809 or IPR2015-00626. Grounds 1-8 in the Petition are different and better, in some respects, than the grounds in the IPR2014-00809 and IPR2015-00626, since Farvat satisfies the claim limitations more closely than Thomson in view of Harris. For example, many of the elements in the challenged claims also appear in Favrat. Often, the only difference between claim elements is that Favrat used said, whereas the 792 patent used the. This Petition, supported by the Declaration of Dr. Hashemi, demonstrates that there is a reasonable likelihood that Petitioner will prevail with respect to at least one of the challenged claims and that each of the challenged claims is unpatentable for the reasons cited in this petition. (See 35 U.S.C. 314(a).) IV. INVALIDITY OF THE 792 PATENT A. Introduction The 792 patent, titled Television Receiver for Digital and Analog Television Signals, was filed July 1, 2014 and originally assigned to Xceive Corp. (Ex. 1101). After Xceive s business faltered, Cresta purchased certain of Xceive s assets including the 792 patent on October 10, 2011. (ITC Amended Complaint, Ex. 1103, p.4.) In January of this year, CrestaTech sued Petitioner and several of 11

its customers for infringing two of the patents it acquired from Xceive. (Id.) The 792 application describes several iterations of a signal output circuit, labeled 140 in Fig. 1 (below). (Id. at 6:49 51.) This output circuit converts the processed IF signals into the desired output signals. (Id.) Figure 2 goes on to illustrate several other desired output signals including analog v. digital, single-ended v. differential, or serial v. parallel. (Id. at Fig. 2; 7:34 35 Turning now to FIG. 2 where alternate embodiments of the signal output circuit are shown. ) B. Prosecution History of the 792 Patent The 792 patent application was filed on July 1, 2004. In the first office action, claims 1 4, 11, 12 and 30 34 1 were rejected under 35 U.S.C. 102(b) as anticipated by the for Favrat application. Claims 5, 10, 13 and 14 were rejected under 35 U.S.C. 103(a) as being unpatentable over the 585 application in view of Oku application. Claims 16 and 17 were rejected under 35 U.S.C. 103(a) as 1 Claim 30 as filed issued as claim 29. (See Ex. 1112, p. 37.) 12

being unpatentable over the 585 application in view of the Oku application, in further view of Gray. Claims 6 9, 15, and 18 29 were indicated to contain allegedly allowable subject matter. (Ex. 1112, pp. 58-63.) In response to the first office action, the applicant amended claim 1 to recite the limitations formerly of claim 24. The applicant also amended all of the other claims to depend from claim 1. Because the subject matter of claim 24 had been indicated as allowable, the applicant argued that independent claim 1 and all depending claims were therefore allowable. The applicant cancelled claim 24 as well as claims 31 34 and requested allowance of all remaining claims. (Ex. 1112 pp. 47-53.) The Examiner then allowed all remaining claims in the application (Ex. 1112, p. 41), despite the fact that the limitation added to claim 1 by amendment was clearly taught in the 585 application. For example, claim 11 of the Favrat application is virtually identical to the allegedly allowable subject matter. (See Ex. 1104 at claim 10 wherein said signal processor applies one of a plurality of finite impulse response filters. ) It appears that the Patent Owner recognized that the 792 patent was invalid and attempted to fix the problem by filing the terminal disclaimer on October 1, 2014 with respect to Favrat. (See Ex. 1112, p. 2.) However, this terminal disclaimer fails to overcome the fact that Favrat is prior art under 102(e) (pre- 13

AIA). Favrat (Ex. 1104) The 792 Patent (Ex. 1101) Inventors Pierre Favrat, Didier Margairaz, Alain-Serge Porret, Dominique Python Pierre Favrat, Didier Margairaz, Alain-Serge Porret, Dominique Python, Friederich Mombers, Richard P. Perring, Philippe Duc, and Benito Carnero Filed September 6, 2002 July 1, 2004 Priority Provisional Application None September 17, 2001 Published April 1, 2004 January 5, 2006 Favrat is a patent granted on an application for patent by another filed in the United States before the invention by the applicant for patent. Another means other than applicants, In re Land, 368 F.2d 866, 151 USPQ 621 (CCPA 1966), in other words, a different inventive entity. The inventive entity is different if not all inventors are the same. The fact that the application and reference have one or more inventors in common is immaterial. Ex parte DesOrmeaux, 25 USPQ2d 2040 (Bd. Pat. App. & Inter. 1992) (The examiner made a pre-aia 35 U.S.C. 102(e) rejection based on an issued U.S. patent to three inventors. The rejected application was a continuation-in-part of the issued parent with an extra inventor. The Board found that the patent was by another and thus could be used in a pre-aia 35 U.S.C. 102(e)/103 rejection of the application.). (See, e.g., MPEP 2136.04.I.) 14

Therefore, Favrat is prior art under pre-aia 35 U.S.C. 102(e). A terminal disclaimer does not overcome a pre-aia 35 U.S.C. 102(e) rejection. (See, e.g., MPEP 2136.05.I.) C. Person of Ordinary Skill in the Art A person of ordinary skill in the art at the time of the alleged invention of the 792 patent ( POSITA ) would have held at least a Masters of Science or higher degree in electrical engineering, as well as about four years of substantial experience designing or doing research in the area of wireless communication receivers and integrated circuit realization of Radio Frequency, known as RF, wireless communication receivers. (Ex. 1113, Hashemi Dec., 10-14.) Additional education may compensate for less experience and vice-versa. (Id.) The field to which the 792 patent is directed is the field of integrated circuits and Radio Frequency communication receivers. (Id.) This is a very demanding field with little margin for error that requires a high level of skill to practice. (Id.) The POSITA should have a holistic knowledge of wireless communication systems; RF integrated circuits; and analog, mixed-signal, and digital integrated circuits. (Id.) V. CLAIM CONSTRUCTION The claims in an inter partes review should be accorded the broadest reasonable construction, as commonly understood by those of ordinary skill in the art in view of the descriptions of the specification. (See 37 C.F.R. 42.100(b).) 15

Because the standard for claim construction at the Patent Office is different from that used during a U.S. District Court litigation, the Petitioner expressly reserves the right to argue a different claim construction in litigation for any term of the 792 patent, as appropriate in that proceeding. A. Summary of Claim Terms Construed The terms that the Petitioner has decided to construe are summarized below: Term Claims Petitioner s Construction RF signal format video and audio baseband signals 1, 8, 13, 18, 20, 22, 26, 28 and 29 1, 2, 4, 5, 7, 8, 11, 14, 15, 18, 20-23 and 26-28 8 and 9 signal having a frequency between 10 khz and 100 GHz distinct signal format, such as analog or digital at least one signal without transmission modulation signal processor 1, 13, 18, 20 and 22-26 digital module that processes signals in the digital domain B. RF signal The specification of the 792 patent defines RF as an abbreviation for radio frequency (Ex. 1101, 1:36), which The Authoritative Dictionary of IEEE Standards Terms identifies as a frequency roughly between 10 khz and 100 GHz. 16

(Ex. 1111, p 912.) The Petitioner construes an RF signal as a signal having a frequency between 10 khz and 100 GHz. The Petitioner s construction is supported by Dr. Hashemi Declaration. (Ex. 1113, Hashemi Dec., 16.) C. format The 792 patent specification draws a distinction between formats and standards : Television signals are transmitted in analog or digital formats and in accordance with a variety of standards. (Ex. 1101, 1:18-20, emphasis added.) The specification further identifies analog or digital TV as examples of formats and NTSC, PAL or SECAM as examples of television standards. (Id. at 1:57-58.) The Petitioner construes format as distinct signal format, such as analog or digital. The Petitioner s construction is supported by Dr. Hashemi Declaration. (Ex. 1113, Hashemi Dec., 17.) D. video and audio baseband signals The specification of the 792 patent admits it was known in the art that a demodulator for an analog television standard will output a video baseband signal and an audio baseband signal. The specification of the 792 patent also admits that it was known in the art that a demodulator for a digital television standard will output one baseband signal an MPEG data stream. (See, e.g., Ex. 1101, 9:63-65 Demodulator circuit 206 operates to demodulate the DTV low-if signal and generates an MPEG data stream as an output signal.) Since the 792 patent 17

specification clearly indicates that a demodulator for digital television formats will output one signal (i.e., a MPEG data stream), the terms video and audio baseband signals [plural] is broadly construed as at least one signal without transmission modulation. Furthermore, claims 8 and 9 do not support a construction of video and audio baseband signals that requires two signals (e.g., a video baseband signal and an audio baseband signal.) Since the video and audio baseband signals in claims 8 and 9 are demodulated and correspond to the digital television format, the video and audio baseband signals in claims 8 and 9 include only one baseband signal an MPEG data stream. The Authoritative Dictionary of IEEE Standards Terms defines baseband signaling as [t]he transmission of a signal at its original frequency, that is, not changed by modulation. Note: It can be an analog or a digital signal. (Ex. 1111, p 87.) The Petitioner construes video and audio baseband signals as at least one signal without transmission modulation. The Petitioner s construction is supported by Dr. Hashemi Declaration. (Ex. 1113, Hashemi Dec., 18-22.) E. signal processor The specification supports a construction of signal processor that is limited to digital signal processing, stating, for example: Another advantage of the dual-format TV receiver of the present 18

invention is that the digital signal processor circuit of the receiver uses a single processing path to process television signals in either analog format or the digital format. Thus, the need to duplicate components is entirely obviated. Finally, the digital signal processor circuit can be readily reconfigured to support multi-standard reception, thereby enabling the television receiver of the present invention to be used in any geographic area of interest. (Ex. 1101, 3:44-54, emphasis added.) A salient feature of the dual-format television receiver of the present invention is the use of a signal programmable digital signal processing path for the processing the received television signal regardless of the television format and standard in which the television signal is transmitted. (Ex. 1101, 9:24-28, emphasis added.) It appears that the preferred embodiment of the signal processor is a programmable, reconfigurable digital signal processor. The Petitioner construes signal processor as a digital module that processes signals in the digital domain. The Petitioner s construction is supported by Dr. Hashemi Declaration. (Ex. 1113, Hashemi Dec., 23-25.) VI. DETAILED EXPLANATIONS OF THE CHALLENGES The detailed explanation provided below, along with the referenced Declaration of Dr. Hashemi (Ex. 1113), demonstrates each ground for each of the challenged claims. Challenged claims 2-29 of the 792 patent each depend from 19

independent claim 1. A. Ground 1: Claims 1, 2, 4, 5, 11 and 24-29 are anticipated by Favrat Every limitation in claim 1 (except for the signal output circuit limitation) is copied from Favrat. However, the signal output circuit limitation in claim 1 is a later genus limitation that is anticipated by an earlier species limitation disclosed by Favrat. Claim 1 comprises a signal output circuit for receiving the digital output signals from the signal processor and for providing one or more output signals corresponding to the digital output signals. In claim 11, the signal output circuit provides output signals in an analog or a digital signal format. A circuit that receives digital output signals and provides output signals in an analog signal format is a digital-to-analog converter (DAC). Therefore, a DAC is one species of the signal output circuit in claim 1. Claim 2 of Favrat comprises a digital-to-analog converter coupled between said signal processor and a first one of said plurality of demodulators, said digitalto-analog converter converting said digital output signals to an analog format. Thus, the a signal output circuit for receiving the digital output signals from the signal processor and for providing one or more output signals corresponding to the digital output signals limitation in claim 1 is a later genus limitation that is anticipated by the earlier species limitation in Favrat, claim 2. (See Eli Lilly & Co. 20

v. Barr Labs., Inc. 251 F.3d 955, 971 (Fed. Cir. 2001) [This court s] case law firmly establishes that a later genus claim limitation is anticipated by, and therefore not patentably distinct from, an earlier species claim. ) 792 Patent - Claim 1 (Ex. 1101) Favrat (Ex. 1104) 1. A television receiver comprising: (Ex. 1113, Hashemi Dec., 28.) See, e.g., claim 1 ( A receiver comprising ), claim 2 ( television format ). See also Figure 2, 3:44-45 ( FIG. 2 is a block diagram of a television receiver according to one embodiment of the present invention. ); 2:43-46, Abstract. a frequency conversion circuit for receiving an input RF signal and for converting the input RF signal to an intermediate frequency signal having an intermediate frequency (IF), the input RF signal encoding information in one of a plurality of television signal formats; (Ex. 1113, Hashemi Dec., 29.) See, e.g., claim 1 ( a tuner for receiving input RF signals and for converting said input RF signals to intermediate signals having an intermediate frequency (IF) ); claim 17 ( converting said input RF ). See also 3:45-48, Figure 2; 3:48-51, 3:51-52 ( For example, tuner 54 can perform a single or dual superheterodyne conversion. ), 3:52-55 ( In one embodiment of the present invention, tuner 54 is a commercially available discrete component and outputs intermediate signals having an intermediate frequency (IF) that is determined by the geographic region of interest. ), 3:59-63. (Ex. 1113, Hashemi Dec., 30.) See, e.g., claim 1 ( said input RF signals encoding information in one of a plurality of formats ), claim 2, claim 17 and 18 See also 3:26-30, at 2:48-51, Abstract, 21

an analog-to-digital converter for sampling the intermediate frequency signal and generating a digital representation thereof a signal processor for processing the digital representation of the intermediate frequency signal in accordance with the television signal format of the input RF signal, the signal processor generating digital output signals indicative of information encoded in the input RF signal, wherein the signal processor applies one of a plurality of finite impulse response filters to the digital representation of the intermediate frequency signal, each of the plurality of finite impulse response corresponding to a format of the input RF signal a signal output circuit for receiving the digital output signals from the signal processor and for providing one or more output signals corresponding to the digital output signals. 3:30-35, 5:27-29 ( receiver 100 can handle television signals in any format (analog or digital) and in any standard (e.g.: NTSC, PAL, SECAM, DVB or ATSC) ) (Ex. 1113, Hashemi Dec., 31.) See, e.g., claim 1 ( an analog-to-digital converter for sampling said filtered intermediate signals and generating a digital representation thereof ). See also 4:5-7, 4:25-27, Figure 2. (Ex. 1113, Hashemi Dec., 32.) See, e.g., claim 1 ( a signal processor for processing said digital representation of said intermediate signals in accordance with said format of said input RF signal, said signal processor generating digital output signals indicative of information encoded in said input RF signal ). See also 2:56-60, 4:51-54, 5:7-22, Figure 2, 4:65. (Ex. 1113, Hashemi Dec., 33.) See, e.g., claim 10 ( wherein said signal processor applies one of a plurality of finite impulse response filters to said digital representation of said intermediate signal, each of said plurality of finite impulse response corresponding to a format of said input RF signal ). See also Figure 2, 4:66-5:1. (Ex. 1113, Hashemi Dec., 34-36.) See, e.g., claim 3 ( The receiver of claim 1, further comprising: a digital-to-analog converter coupled between said signal processor and a first one of said plurality of demodulators, said digital-to-analog 22

converter converting said digital output signals to an analog format. ). See also 5:54-58 ( In cases where analog demodulator 66a receives analog input signals only, a digital-toanalog converter (DAC) (not shown) can be included between the output terminal of DSP 64 and the input terminal of analog demodulator 66a. ). 792 Patent - Claim 2 (Ex. 1101) Favrat (Ex. 1104) 2. The television receiver of claim 1, (Ex. 1113, Hashemi Dec., 37.) wherein the plurality of television See above discussion of 792 patent, signal formats comprises claim 1. See also Ex. 1104 at claims 1 an analog television format and a digital television format. and 2. (Ex. 1113, Hashemi Dec., 37.) See above discussion of 792 patent, claim 1. See also Ex. 1104 at claim 1, claim 2 ( said plurality of formats comprise an analog television format and a digital television format ) 792 Patent - Claim 4 (Ex. 1101) Favrat (Ex. 1104) 4. The television receiver of claim 1, (Ex. 1113, Hashemi Dec., 38.) wherein the signal output circuit See above discussion of 792 patent, provides claim 1. a first output signal being a video baseband signal corresponding to an analog television format and a second output signal being an audio baseband signal corresponding to the analog television format. (Ex. 1113, Hashemi Dec., 38.) See, e.g., 5:49-52 ( demodulators 66 include a demodulator for analog television signals 66 a ); 5:59-62 ( Analog demodulator 66a provides three output signals: a Composite Video Baseband Signal (CVBS) containing the video information, and audio 1 and audio 2 containing the audio information. ). 792 Patent - Claim 5 (Ex. 1101) Favrat (Ex. 1104) 5. The television receiver of claim 4, (Ex. 1113, Hashemi Dec., 39.) further comprising: See above discussion of 792 patent, 23

a first decoder circuit coupled to decode the video baseband signal for providing video display signals corresponding to the analog television format; and a second decoder circuit coupled to decode the audio baseband signal for providing audio signals corresponding to the analog television format claim 4. (Ex. 1113, Hashemi Dec., 40.) See, e.g., 5:46-48 ( The video and audio baseband signals are usually coupled to video and audio decoders before being displayed or playback on a view screen. ); 1:55-57 (describing prior art Figure 1, [t]he baseband signals are coupled to appropriate video and audio decoders to generate the display signals (e.g. RGB) or sound. ). (Ex. 1113, Hashemi Dec., 41.) See, e.g., 5:46-48 ( The video and audio baseband signals are usually coupled to video and audio decoders before being displayed or playback on a view screen. ); 1:55-57 (describing prior art Figure 1, [t]he baseband signals are coupled to appropriate video and audio decoders to generate the display signals (e.g. RGB) or sound. ). 792 Patent - Claim 11 (Ex. 1101) Favrat (Ex. 1104) 11. The television receiver of claim 1, (Ex. 1113, Hashemi Dec., 42.) wherein the signal output circuit See above discussion of 792 patent, provides claim 1. output signals in an analog or a digital signal format. (Ex. 1113, Hashemi Dec., 42.) See, e.g., 6:2-5 ( An additional digitalto-analog converter may be coupled to the output terminal of demodulator 66a if analog output signals are desired. ), claim 3 ( The receiver of claim 1, further comprising: a digital-to-analog converter coupled between said signal processor and a first one of said plurality of demodulators, said digitalto-analog converter converting said 24

digital output signals to an analog format. ); see also id. at 5:54-58 ( In cases where analog demodulator 66a receives analog input signals only, a digital-to-analog converter (DAC) (not shown) can be included between the output terminal of DSP 64 and the input terminal of analog demodulator 66a. ). 792 Patent - Claim 24 (Ex. 1101) Favrat (Ex. 1104) 24. The television receiver of claim (Ex. 1113, Hashemi Dec., 43.) 1, wherein See above discussion of 792 patent, the plurality of finite impulse response filters are stored in a memory, and the signal processor indexes the memory to retrieve one of the plurality of finite impulse response filters. claim 1. (Ex. 1113, Hashemi Dec., 43.) See, e.g., claim 11 ( The receiver of claim 10, wherein said plurality of finite impulse response filters are stored in a memory, and said signal processor indexes said memory to retrieve one of said plurality of finite impulse response filters. ), claim 10 ( wherein said signal processor applies one of a plurality of finite impulse response filters to said digital representation of said intermediate signal, each of said plurality of finite impulse response corresponding to a format of said input RF signal. ). See also 4:60-64 ( In one embodiment, the coefficients of the filter functions are stored in a look-up table in a memory 70. DSP 64 retrieves the coefficients from memory 70 to be applied to the incoming digital signals. ). 792 Patent - Claim 25 (Ex. 1101) Favrat (Ex. 1104) 25. The television receiver of claim (Ex. 1113, Hashemi Dec., 44.) 1, wherein the signal processor See above discussion of 792 patent, 25

comprises claim 1. a first computing unit and a second (Ex. 1113, Hashemi Dec., 44.) computing unit, the first computing See, e.g., claim 12 ( The receiver of unit processing a real part of the finite claim 10, wherein said signal processor impulse response filter operation comprises a first computing unit and a while the second computing unit second computing unit, said first processing an imaginary part of the computing unit processing a real part of finite impulse response filter said finite impulse response filter operation. operation while said second computing unit processing an imaginary part of said finite impulse response filter operation. ), claim 10. See also 5:1-6 ( Furthermore, in the present embodiment, DSP 64 includes two computing units to speed up the computation time. Specifically, the filtering operations of the real and imaginary parts in the frequency domain are carried out in parallel. In other embodiments, DSP 64 may include only one computing unit. ). 792 Patent - Claim 26 (Ex. 1101) Favrat (Ex. 1104) 26. The television receiver of claim (Ex. 1113, Hashemi Dec., 45.) 1, further comprising See above discussion of 792 patent, a format/standard selection circuit coupled to the signal processor, the format/standard selection circuit generating a select signal indicative of a format of the input RF signal and the signal processor selecting a finite impulse response filter in response to the select signal. claim 1. (Ex. 1113, Hashemi Dec., 45.) See, e.g., claim 13 ( The receiver of claim 10, wherein said channel filter further comprises a standard selection circuit coupled to said signal processor, said standard selection circuit generating a select signal indicative of a format of said input RF signal and said signal processor selecting a finite impulse response filter in response to said select signal. ), claim 10. See also 4:55-5:22, 4:55-60 ( channel filter 58 includes a standard selection circuit 68 for selecting between the 26

several analog television standards and the several digital television standards. DSP 64 applies the appropriate filter function, such as an impulse response, to the digital signals depending on the state of standard selection circuit 68. ), Figure 2 (depicting the standard selection circuit feeding the DSP (64)). 792 Patent - Claim 27 (Ex. 1101) Favrat (Ex. 1104) 27. The television receiver of claim (Ex. 1113, Hashemi Dec., 46.) 26, wherein the format/standard See above discussion of 792 patent, selection circuit claim 26. generates the select signal in response to an input signal from a user. (Ex. 1113, Hashemi Dec., 46.) See, e.g., claim 14 ( The receiver of claim 13, wherein said standard selection circuit generates said select signal in response to an input signal from a user. ). See also 5:7-10 ( Standard selection circuit 68 can be implemented in one of many ways. The selection of the correct standard can be made manually by the user of the television system, such as by activating a switch ). 792 Patent - Claim 28 (Ex. 1101) Favrat (Ex. 1104) 28. The television receiver of claim (Ex. 1113, Hashemi Dec., 47.) 26, wherein the format/standard selection circuit See above discussion of 792 patent, claim 26. generates the select signal by detecting carrier signals identifying one of the formats of the input RF signals. (Ex. 1113, Hashemi Dec., 47.) See, e.g., claim 15 ( The receiver of claim 13, wherein said standard selection circuit generates said select signal by detecting carrier signals identifying one of said formats of said input RF signals. ) See also 5:7-22 ( Standard selection circuit 68 can be implemented in one of many ways. In the present 27

embodiment, auto-detection is implemented by detecting in the baseband signals the presence or absence of carrier signals which uniquely identify the television standards. For example, analog television signals can be identified by the analog visual carrier signal while digital television signals can be identified by the pilot carrier. Each demodulator in bank 66 generates a signal which is fed back to standard selection circuit 68 indicating which television standard the input signal is encoded. ). 792 Patent - Claim 29 (Ex. 1101) Favrat (Ex. 1104) 29. The television receiver of claim (Ex. 1113, Hashemi Dec., 48.) 1, wherein the input RF signal comprises See above discussion of 792 patent, claim 1. an RF signal received from terrestrial broadcast, an RF signal received from satellite broadcast, and an RF signal received from cable transmission. (Ex. 1113, Hashemi Dec., 48.) See, e.g., claim 16 ( The receiver of claim 1, wherein said input RF signals comprise RF signals received from one of terrestrial broadcast, from satellite broadcast, and from cable transmission. ). See also 6:26-30 ( the television receiver of the present invention can be used to receive television signals distributed in any manner and provides excellent reception performance. Thus, the TV receiver of the present invention can be used for the reception of terrestrial broadcast and cable transmission. ); 1:24-28 ( A television or video recorder includes a television signal receiver (or television receiver) to receive terrestrial broadcast, cable television or satellite broadcast 28

television signals and to process the television signals into the appropriate video signals for display or for recording. ). B. Ground 2: Claim 3 is obvious over Favrat in view of Arambepola Arambepola teaches a multi-standard television receiver, which processes signals in the digital domain. (See, e.g., Ex. 1139 at Arambepola, 1:6-11 ( The present invention relates to a digital receiver. Such a receiver may be used for receiving digital terrestrial television (DTTV) signals and digital audio broadcasting (DAB) signals. Such a receiver is suitable for orthogonal frequency division multiplex (OFDM) reception but may be suitable for receiving signals with other modulation standards. ).) Therefore, a POSITA would be motivated to use concepts from Arambepola with Favrat, which also teaches a multi-standard television receiver. (Ex. 1113, Hashemi Dec., 49.) Since Favrat already teaches the integration of a receiver onto the same piece of integrated circuit the motivation, a POSITA would be motivated to incorporate Arambepola idea of using monolithic integrated circuits. (See, e.g., Favrat, 6:12-15: In one embodiment of the present invention, TV receiver 50 is an integrated circuit where tuner 54, channel filter 58 and demodulators 66 are all integrated onto the same piece of integrated circuit. ) (Ex. 1113, Hashemi Dec., 50.) 29

792 Patent - Claim 3 (Ex. 1101) 3. The television receiver of claim 1, wherein the television receiver is formed as a monolithic integrated circuit. Favrat (Ex. 1104) and Arambepola (Ex. 1139) See above discussion of 792 patent, claim 1. (Ex. 1113, Hashemi Dec., 49-51.) See, e.g., Ex. 1104, 6:12-15: In one embodiment of the present invention, TV receiver 50 is an integrated circuit where tuner 54, channel filter 58 and demodulators 66 are all integrated onto the same piece of integrated circuit. See, e.g., Ex. 1139, 4:2-5 ( The receiver is embodied as one or more monolithic integrated circuits and the filters 7 and 8 are integrated therein as any suitable implementation. ); and id. at 3:15-21 ( It is thus possible to provide an arrangement which the passbands of adjustable filters for baseband components to be adjusted accurately and relatively quickly. Such an arrangement makes possible the use of integrated analog filters which do not need to be highly specified in respect of their passbands. It is therefore possible to provide a receiver of improved performance and reduced cost of manufacture. ). C. Ground 3: Claim 6 is obvious over Favrat in view of Yang Yang teaches a multi-standard television receiver. Therefore, a POSITA would be motivated to use concepts from Yang with Favrat, which also teaches a multi-standard television receiver. (Ex. 1113, Hashemi Dec., 52-53.) Favrat provides the motivation to add Yang s plurality of detectors. For example, Favrat teaches a television (TV) receiver [that] includes a multi-standard channel filter (Ex. 1104 at 3:27-28) which uses a plurality of demodulators (Id. at claim 1) to receive television signals in a variety of television standards and 30

formats (Id. at 3:29-30), and the background of Favrat describes NTSC, PAL or SECAM (Id. at 2:7) as examples of television standards. Yang provides selectable NTSC, PAL and ATSC detectors that a POSITA would use. (Ex. 1113, Hashemi Dec., 53-54.) (Ex. 1105, Yang, Fig. 4.) 792 Patent - Claim 6 (Ex. 1101) Favrat (Ex. 1104) and Yang (Ex. 1105) 6. The television receiver of claim 5, See above discussion of 792 patent, wherein the first decoder circuit claim 5. comprises a PAL/SECAM/NTSC decoder circuit. (Ex. 1113, Hashemi Dec., 52-54.) See, e.g., 1104 at 2:7, 2:55-57, 3:27-28, 3:29-30, 4:32-35. See also, e.g., Ex. 1105, Fig. 46:21-32 ( As described above. the multitelevision of the present invention is capable of receiving several broadcasting signals of the NTSC 31

broadcasting system, the PAL broadcasting system. and the SECAM broadcasting system. Furthermore. the multi-television is capable of automatically correcting a difference of the chrominance level of the signals received via each broadcasting system by programming the gain control data of each broadcasting system in a microcomputer. As a result. a user can properly view a program corresponding to video signals of a plurality of different broadcasting systems. ). D. Ground 4: Claim 7, 8, 9 and 12 are obvious over Favrat in view of Wilkie Wilkie teaches a system suitable for the transfer of multimedia signals. Therefore, a POSITA would be motivated to use concepts from Wilkie to enable the transfer of multimedia signals in Favrat. It would have obvious for a POSITA to incorporate Wilkie s selectable driver circuit for converting a signal from singleended to differential if a subsequent demodulator required a differential signal. (Id.) (Ex. 1113, Hashemi Dec., 56-59.) Wilkie teaches a signal output circuit with a differential output terminal that is selectable. (See, e.g., Ex. 1106, Wilkie, Abstract, An apparatus for transmitting an analog image signal representing an image over a bus including a driver circuit which receives a single ended analog image signal from a media source and provides a differential analog image signal and a switch circuit which selectively 32

provides the differential analog image signal to the bus in response to control information; FIG. 11B (below); see also Ex. 1113, Hashemi Dec., 60.) (Ex. 1106, Wilkie, Fig. 11B.) 792 Patent - Claim 7 (Ex. 1101) Favrat (Ex. 1104) and Wilkie (Ex. 1106) 7. The television receiver of claim 1, See above discussion of 792 patent, wherein the signal output circuit claim 1. provides a first output signal and a second output signal corresponding to the digital output signals, the first output signal and the second output signal being differential output (Ex. 1113, Hashemi Dec., 55-60.) See the a signal output circuit for receiving the digital output signals from the signal processor and for providing one or more output signals corresponding to the digital output signals limitation of claim 1, above. (Ex. 1113, Hashemi Dec., 55-60.) See also, e.g., 1106, Fig. 11B, 33

signals corresponding to a digital television format. Abstract ( An apparatus for transmitting an analog image signal representing an image over a bus including a driver circuit which receives a single ended analog image signal from a media source and provides a differential analog image signal and a switch circuit which selectively provides the differential analog image signal to the bus in response to control information ). (Ex. 1113, Hashemi Dec., 55-60.) Ex. 1104 at 4:53-54 ( DSP 64 processes the digital signals according to the television standard to which the input RF signal is encoded. ), 5:42-45, 6:6-7. See, e.g., claim 2 ( said plurality of formats comprise an analog television format and a digital television format ). 792 Patent - Claim 8 (Ex. 1101) Favrat (Ex. 1104) 8. The television receiver of claim 7, (Ex. 1113, Hashemi Dec., 61.) further comprising: See above discussion of 792 patent, a demodulator circuit for demodulating the first output signal and the second output signal according to the television signal format of the input RF signal, the demodulator circuit generating video and audio baseband signals corresponding to the format of the input RF signal claim 7. (Ex. 1113, Hashemi Dec., 62.) See, e.g., claim 1 ( a plurality of demodulators, each coupled to receive output signals from said signal processor, each of said demodulators for demodulating said digital output signals according to one of said formats of said input RF signal, each of said demodulators generating video and audio baseband signals corresponding to said format of said input RF signal. ), 5:42-44, Figure 2 (depicting the bank of demodulators 66 receiving the digital output signals from the 34

a decoder circuit coupled to decode the video and audio baseband signals for providing video and audio display signals corresponding to the digital television format. signal processor (DSP) 64.), 5:49-52, 5:59-62. (Ex. 1113, Hashemi Dec., 63.) See, e.g., 5:46-48 ( The video and audio baseband signals are usually coupled to video and audio decoders before being displayed or playback on a view screen. ), 6:6-7, 1:55-57. 792 Patent - Claim 9 (Ex. 1101) Favrat (Ex. 1104) 9. The television receiver of claim 8, (Ex. 1113, Hashemi Dec., 64.) wherein the video and audio baseband See above discussion of 792 patent, signals comprise claim 8. a MPEG data stream and the decoder circuit comprises a MPEG decoder circuit. (Ex. 1113, Hashemi Dec., 64.) See, e.g., 6:6-10 ( Digital demodulator 66 b operates to decode the incoming digital television signal. Typically, digital television signals are modulated in a VSB, QAM or COFDM scheme. Digital demodulator 66 b generates an MPEG data stream as output signals. ). 792 Patent - Claim 12 (Ex. 1101) Favrat (Ex. 1104) and Wilkie (Ex. 1106) 12. The television receiver of claim 1, (Ex. 1113, Hashemi Dec., 65.) wherein the signal output circuit See above discussion of 792 patent, comprises one or more output terminals, claims 1 and 7. each of the one or more output terminals of the signal output circuit comprises a single-ended output terminal or a differential output terminal E. Ground 5: Claim 10 is obvious over Favrat in view of Vorenkamp Vorenkamp teaches an integrated receiver with a tuner for converting a received signal to a digital IF signal. (See, e.g., Ex. 1107, Vorenkamp, Abstract). Therefore, a POSITA would be motivated to use concepts from Vorenkamp with 35

Favrat, which also teaches an integrated receiver with a tuner for converting a received signal to a digital IF signal. (Ex. 1113, Hashemi Dec., 68-70.) It would have been obvious to a POSITA to incorporate the Vorenkamp VGA to provide automatic gain control (AGC) and improve the dynamic range of the receiver. (See, e.g., Ex. 1108, Vorenkamp, 53:29-33 The improved dynamic range of the VGA compensates for increased variations in signal amplitude caused by irregularities in the external differential filter 5430. ) (Ex. 1113, Hashemi Dec., 68-70.) 36

(Ex. 1107, Vorenkamp, Fig. 5 and Fig. 83, annotation added.) 792 Patent - Claim 3 (Ex. 1101) Favrat (Ex. 1104) and Vorenkamp (Ex. 1107) 10. The television receiver of claim 1, (Ex. 1113, Hashemi Dec., 66.) further comprising: See above discussion of 792 patent, a bandpass filter coupled to receive the intermediate frequency signal from the frequency conversion circuit and generate a filtered intermediate frequency signal; and a variable gain amplifier coupled to receive the filtered intermediate frequency signal and provide the amplified, filtered intermediate frequency signal to the analog-to-digital converter. claim 1. (Ex. 1113, Hashemi Dec., 67.) See, e.g., Ex. 1104, claim 17, applying a first filter function to said intermediate signals, said first filter function being an anti-aliasing filter and having a center frequency. ), Figure 2; id. at 4:3-7 ( Next, TV receiver 50 includes multi-standard channel filter 58 for filtering and processing the intermediate signals from tuner 54. Multi-standard channel filter 58 includes an anti-aliasing filter 60, an analog-to-digital converter (ADC) 62 and a digital signal processor (DSP) 64. ), 4:20-25 4:31-33. (Ex. 1113, Hashemi Dec., 68-71.) See, e.., Ex. 1107, 107:11-12 ( The signal at input IF IN is fed into a variable gain amplifier (VGA) 8317. ). See also, e.g., Ex. 1107, Figs. 5 and 83 (illustrating variable gain amplifier (VGA) between a bandpass filter (BPF) and an analog-to-digital converter (ADC)), 53:29-33. F. Ground 6: Claims 13-15 and 18 is obvious over Favrat in view of Oku Oku and Favrat both teach a multi-standard television receiver. Therefore, a POSITA would be motivated to use concepts from Oku in Favrat s signal output 37

circuit. It would have been obvious to a POSITA to incorporate Oku s driver circuits for interfacing with a subsequent demodulator and/or decoder. (Ex. 1113, Hashemi Dec., 74.) Many of the challenged claims recite the different permutations of these desired output signals. (See, e.g., id. at claim 13.) Converting an output signal from one desired output form to another is not patentable. A person of ordinary skill in the art ( POSITA ) would know that a digital-to-analog converter ( DAC ) would be necessary if the desired output format was analog instead of digital. (Ex. 1113, Hashemi Dec. 75). Likewise, a POSITA would know that a single to differential-ended converter was necessary to convert a single-ended output to a differential-ended output, if a differential-ended output was desired. (See, e.g., Ex. 1113, Hashemi Dec. 56-58, 83). Similarly, a POSITA would know that a parallel-to-serial converter (i.e., serializer ) was necessary if the desired output format was serial rather than parallel. (See, e.g., Ex. 1113, Hashemi Dec. 100-101). Such use of known elements in such predictable ways is obvious. KSR Intern. Co. v. Teleflex Inc., 550 U.S. 398, 421 (2007). All of the claimed options are well within the grasp of a POSITA, as evidenced by the legions of prior art references using these options. 792 Patent - Claim 13 (Ex. 1101) Favrat (Ex. 1104) and Oku (Ex. 1108) 13. The television receiver of claim 1, (Ex. 1113, Hashemi Dec. 72.) wherein the signal output circuit See above discussion of 792 patent, 38

comprises: claim 1. a first digital-to-analog converter (Ex. 1113, Hashemi Dec. 73.) coupled to receive digital output See, Ex. 1104, claim 3 ( a digital-toanalog converter coupled between said signals from the signal processor and convert the digital output signals to signal processor and a first one of said analog output signals; plurality of demodulators, said digitalto-analog converter converting said digital output signals to an analog format ), 5:54-58 ( In cases where analog demodulator 66a receives analog input signals only, a digital-to-analog converter (DAC) (not shown) can be included between the output terminal of DSP 64 and the input terminal of analog a first driver circuit for driving the analog output signals from the first digital-to-analog converter onto a first output terminal; demodulator 66a. ). (Ex. 1113, Hashemi Dec. 74-76.) a second driver circuit for driving the analog output signals from the first digital-to-analog converter onto a second output terminal; Ex. 1108 at Figures 1, 4, 6-7, 9-17; id. at 2:59-63 ( An object of the present invention is to solve the above problems, facilitate provisions to broadcasted variety of picture formats and realize simultaneous reception of an analog broadcast.), 7:24-32, 7:58-62, 8:45-58, 9:18-40, 12:58-62. (Ex. 1113, Hashemi Dec. 77.) 39

a second digital-to-analog converter coupled to receive digital output signals from the signal processor encoding audio information and convert the digital output signals to analog output signals; and a third driver circuit for driving the analog output signals from the second digital-to-analog converter onto a third output terminal, Ex. 1108, Oku, Fig. 2 and 4. (Ex. 1113, Hashemi Dec. 78.) See, Favrat, claim 3 ( a digital-toanalog converter coupled between said signal processor and a first one of said plurality of demodulators, said digitalto-analog converter converting said digital output signals to an analog format ). (Ex. 1113, Hashemi Dec. 79.) wherein the first and second output terminals provide signals indicative of video and audio information encoded in the input RF signal and the third output terminal provides signals indicative of audio information encoded in the input RF signal. Ex. 1108, Oku, Figs. 2 and 4. (Ex. 1113, Hashemi Dec. 80.) See above discussion of 792 patent, claim 4. See also Ex. 1104 at 5:49-52 ( demodulators 66 include a demodulator for analog television signals 66 a ), 5:59-62 ( Analog demodulator 66a provides three output signals: a Composite Video Baseband Signal (CVBS) containing the video information, and audio 1 and audio 2 containing the audio information. ). 40

792 Patent - Claim 14 (Ex. 1101) Favrat (Ex. 1104) and Oku (Ex. 1108) 14. The television receiver of claim (Ex. 1113, Hashemi Dec. 81.) 13, wherein the first driver circuit See above discussion of 792 patent, comprises claim 13. a single-ended driver circuit for driving analog output signals corresponding to an analog television format, the analog output signals being video baseband signals; and the third driver circuit comprises a single-ended driver circuit for driving analog output signals corresponding to the analog television format, the analog output signals being audio baseband signals. (Ex. 1113, Hashemi Dec. 81.) Ex. 1108 at Figures 2 and 4; Ex. 1104 at 5:49-52 ( demodulators 66 include a demodulator for analog television signals 66 a ), 5:59-62 ( Analog demodulator 66a provides three output signals: a Composite Video Baseband Signal (CVBS) containing the video information, and audio 1 and audio 2 containing the audio information. ). (Ex. 1113, Hashemi Dec. 81.) Ex. 1108 at Figures 2 and 4; Ex. 1104 at 5:49-52 ( demodulators 66 include a demodulator for analog television signals 66 a ), 5:59-62 ( Analog demodulator 66a provides three output signals: a Composite Video Baseband Signal (CVBS) containing the video information, and audio 1 and audio 2 containing the audio information. ). 792 Patent - Claim 15 (Ex. 1101) Favrat (Ex. 1104) and Oku (Ex. 1108) 15. The television receiver of claim (Ex. 1113, Hashemi Dec. 82-83.) 13, wherein the second driver circuit See above discussion of 792 patent, comprises claim 13. a differential output driver circuit for driving analog output signals corresponding to a digital television format, the analog output signals being DTV low-if signals, and (Ex. 1113, Hashemi Dec. 82-83.) Ex. 1108 at Figures 2 and 4; Ex. 1104 at 5:49-52 ( demodulators 66 include a demodulator for analog television signals 66 a, a demodulator for digital television signals 66 b and a demodulator 66 c for digital data channels. ); 6:6-7 ( Digital demodulator 66b operates to decode the 41

wherein the second output terminal comprises a first differential output terminal and a second differential output terminal. incoming digital television signal. ). (Ex. 1113, Hashemi Dec. 82-83.) Ex. 1108 at Figures 2 and 4; Ex. 1104 at 5:49-52 ( demodulators 66 include a demodulator for analog television signals 66 a, a demodulator for digital television signals 66 b and a demodulator 66 c for digital data channels. ); 6:6-7 ( Digital demodulator 66b operates to decode the incoming digital television signal. ). 792 Patent - Claim 18 (Ex. 1101) Favrat (Ex. 1104) and Oku (Ex. 1108) 18. The television receiver of claim 1, (Ex. 1113, Hashemi Dec. 84.) wherein the signal output circuit See above discussion of 792 patent, comprises: claim 1. a first digital-to-analog converter coupled to receive digital output signals from the signal processor and convert the digital output signals to analog output signals; a first driver circuit for driving the analog output signals from the first digital-to-analog converter onto a first output terminal; (Ex. 1113, Hashemi Dec. 85.) See, Ex. 1104, claim 3 ( a digital-toanalog converter coupled between said signal processor and a first one of said plurality of demodulators, said digitalto-analog converter converting said digital output signals to an analog format ); id. at 5:54-58 ( In cases where analog demodulator 66a receives analog input signals only, a digital-to-analog converter (DAC) (not shown) can be included between the output terminal of DSP 64 and the input terminal of analog demodulator 66a. ). (Ex. 1113, Hashemi Dec. 86.) 42

a second driver circuit for driving the analog output signals from the first digital-to-analog converter, the second driver circuit comprising a differential output driver circuit having a first differential output terminal and a second differential output terminal, the first differential output terminal being coupled to the first output terminal and the second differential output terminal being coupled to a second output terminal; a second digital-to-analog converter coupled to receive digital output signals from the signal processor encoding audio information and convert the digital output signals to analog output signals; and a third driver circuit for driving the analog output signals from the second digital-to-analog converter onto the second output terminal, Ex. 1108, Oku, Figs. 2 and 4, see also id. at Figures 1, 4, 6-7, 9-17; id. at 2:59-63 ( An object of the present invention is to solve the above problems, facilitate provisions to broadcasted variety of picture formats and realize simultaneous reception of an analog broadcast.). (Ex. 1113, Hashemi Dec. 87.) Ex. 1108, Oku, Figs. 2 and 4, see also id. at Figures 1, 4, 6-7, 9-17; id. at 2:59-63 ( An object of the present invention is to solve the above problems, facilitate provisions to broadcasted variety of picture formats and realize simultaneous reception of an analog broadcast.). (Ex. 1113, Hashemi Dec. 88.) See, Favrat, claim 3 ( a digital-toanalog converter coupled between said signal processor and a first one of said plurality of demodulators, said digitalto-analog converter converting said digital output signals to an analog format ). (Ex. 1113, Hashemi Dec. 89.) wherein the first and second output terminals provide differential output signals indicative of video and audio (Ex. 1108, Oku, Figs. 2 and 4.) (Ex. 1113, Hashemi Dec. 90.) See above discussion of 792 patent, claim 4; see also Ex. 1104 at 5:49-52 43

information encoded in the input RF signal when the input RF signal has a digital television signal format; and the first output terminal provides video information encoded in the input RF signal and the second output terminal provides signals indicative of audio information encoded in the input RF signal when the input RF signal has an analog television signal format ( demodulators 66 include a demodulator for analog television signals 66 a ), 5:59-62 ( Analog demodulator 66a provides three output signals: a Composite Video Baseband Signal (CVBS) containing the video information, and audio 1 and audio 2 containing the audio information. ). (Ex. 1113, Hashemi Dec. 90.) See above discussion of 792 patent, claim 4; see also Ex. 1104 at 5:49-52 ( demodulators 66 include a demodulator for analog television signals 66 a ), 5:59-62 ( Analog demodulator 66a provides three output signals: a Composite Video Baseband Signal (CVBS) containing the video information, and audio 1 and audio 2 containing the audio information. ). G. Ground 7: Claims 16, 17 and 19 are obvious over Favrat in view of Oku Oku and Favrat both teach a multi-standard television receiver. Gray teaches a suitable interface for analog multimedia signals. Therefore, a POSITA would be motivated to use concepts from Oku and Gray in Favrat s signal output circuit. It would have been obvious to incorporate Gray s low pass filter with Oku s driver circuit for removing any of the artifacts produced by the DAC before interfacing with a subsequent demodulator and/or decoder. (Ex. 1113, Hashemi Dec., 91-94.) 792 Patent - Claim 16 (Ex. 1101) Favrat (Ex. 1104), Oku (Ex. 1108) and Gray (Ex. 1109) 44

16. The television receiver of claim 13, wherein the signal output circuit further comprises: a low pass filter coupled between the first digital-to-analog converter and the first and second driver circuits, the low pass filter providing low pass filtering function. 792 Patent - Claim 17 (Ex. 1101) 17. The television receiver of claim 13, wherein the signal output circuit further comprises: a low pass filter coupled between the second digital-to-analog converter and the third driver circuit, the low pass filter providing low pass filtering function 792 Patent - Claim 19 (Ex. 1101) 19. The television receiver of claim 18, wherein the signal output circuit further comprises: a low pass filter coupled between the first digital-to-analog converter and the first and second driver circuits, the low pass filter providing low pass filtering function. (Ex. 1113, Hashemi Dec. 91-94.) See above discussion of 792 patent, claim 13. See also Ex. 1108 at Figures 1, 4, 6-7, 9-17; id. at 2:59-63. (Ex. 1113, Hashemi Dec. 91-94.) See, e.g., Ex. 1109, Gray, 15:21-22 ( A low pass filter (111) removes any of the artifacts produced during the conversion from digital to analog. ); Figure 9. Favrat (Ex. 1104), Oku (Ex. 1108) and Gray (Ex. 1109) (Ex. 1113, Hashemi Dec. 95-96.) See above discussion of 792 patent, claim 13; see also Ex. 1108 at Figures 1, 4, 6-7, 9-17; id. at 2:59-63. (Ex. 1113, Hashemi Dec. 95-96.) See, e.g., Ex. 1109, Gray, 15:21-22 ( A low pass filter (111) removes any of the artifacts produced during the conversion from digital to analog. ) ; Figure 9. Favrat (Ex. 1104), Oku (Ex. 1108) and Gray (Ex. 1109) (Ex. 1113, Hashemi Dec. 97-98.) See above discussion of 792 patent, claim 13; see also Ex. 1108 at Figures 1, 4, 6-7, 9-17; id. at 2:59-63. (Ex. 1113, Hashemi Dec. 97-98.) See, e.g., Ex. 1109, Gray, 15:21-22 ( A low pass filter (111) removes any of the artifacts produced during the conversion from digital to analog. ) ; Figure 9. 45

H. Ground 8: Claims 20-23 are obvious over Favrat in view of Oku and further in view of Eglit and Wilkie Oku and Favrat both teach a multi-standard television receiver. Eglit and Wilkie teach suitable interfaces for multimedia signals. (Ex. 1113, Hashemi Dec. 100-101.) Therefore, a POSITA would be motivated to use concepts from Oku, Eglit and Wilkie in Favrat s signal output circuit to enable the transfer of multimedia signals in Favrat. (Ex. 1113, Hashemi Dec. 100-101.) 792 Patent - Claim 20 (Ex. 1101) 20. The television receiver of claim 1, wherein the signal output circuit comprises: a first serializer circuit coupled to receive the digital output signals from the signal processor and convert the digital output signals to a serial digital data stream; Favrat (Ex. 1104), Oku (Ex. 1108), Eglit (Ex. 1110) and Wilkie (Ex. 1106) (Ex. 1113, Hashemi Dec. 99.) See, e.g., Ex. 1104, Favrat, as cited in section VI.A.1 above, with respect to claim 1. (Ex. 1113, Hashemi Dec. 100-102.) a first driver circuit comprising a differential output driver for driving the Ex. 1110, Eglit, Fig. 6; id. at claim 4 ( a processor, coupled to said computer data bus, for retrieving said compressed motion video data from said memory, and serializing said compressed motion video data to produce serialized compressed motion video data ). (Ex. 1113, Hashemi Dec. 103.) 46

serial digital data stream from the first serializer onto a first output terminal and a second output terminal; a first digital-to-analog converter coupled to receive digital output signals from the signal processor encoding audio information and convert the digital output signals to analog output signals; and (Ex. 1106, Wilkie, Fig. 11B); see also Ex. 1106, Wilkie at Abstract ( An apparatus for transmitting an analog image signal representing an image over a bus including a driver circuit which receives a single ended analog image signal from a media source and provides a differential analog image signal and a switch circuit which selectively provides the differential analog image signal to the bus in response to control information ). (Ex. 1113, Hashemi Dec. 104.) a second driver circuit for driving the analog output signals from the first digital-to-analog converter onto a third output terminal, Ex. 1108, Oku, Fig. 2; Ex. 1108 at Figures 2 and 4. (Ex. 1113, Hashemi Dec. 105.) 47

wherein the first and second output terminals provide differential output signals indicative of video and audio information encoded in the input RF signal when the input RF signal has a digital television signal format and provide differential output signal indicative of video information when the input RF signal has an analog television signal format; and the third output terminal provides signals indicative of audio information encoded in the input RF signal when the input RF signal has an analog television signal format. 792 Patent - Claim 21 (Ex. 1101) Ex. 1108, Oku, Fig. 2; Ex. 1108 at Figures 2 and 4. (Ex. 1113, Hashemi Dec. 106-7.) See, e.g., Ex. 1104, Favrat, as described in section VI.C.2 above, with respect to claim 7, see also, e.g., Ex. 1104, Favrat, as cited in section VI.A.7 above, with respect to claim 9. See also Ex. 1104 at 4:53-54 ( DSP 64 processes the digital signals according to the television standard to which the input RF signal is encoded. ), 5:49-52 5:59-62. (Ex. 1113, Hashemi Dec. 106-7.) See, e.g., Ex. 1104, Favrat, as cited in section VI.A.4 above, with respect to claim 4. (Ex. 1113, Hashemi Dec. 106-7.) See, e.g., Ex. 1104, Favrat, as cited in section VI.A.4 above, with respect to claim 4. See also Ex. 1106, Wilkie at Abstract ( An apparatus for transmitting an analog image signal representing an image over a bus including a driver circuit which receives a single ended analog image signal from a media source and provides a differential analog image signal and a switch circuit which selectively provides the differential analog image signal to the bus in response to control information ); id. at FIG. 11B.) Favrat (Ex. 1104), Oku (Ex. 1108), Eglit (Ex. 1110) and Wilkie (Ex. 1106) 48

21. The television receiver of claim 20, wherein the first, second and third output terminals of the signal output circuit are coupled to a demodulator-decoder circuit, the demodulator-decoder circuit demodulating the serial digital data stream when the data stream corresponds to a digital television format: the demodulator-decoder circuit decoding the serial digital data stream when the data stream corresponds to an analog television format: 792 Patent - Claim 22 (Ex. 1101) 22. The television receiver of claim 20, wherein the signal output circuit further comprises: a second digital-to-analog converter coupled to receive the digital output signals from the signal processor and convert the digital output signals to analog output signal; and (Ex. 1113, Hashemi Dec. 108.) See above discussion of 792 patent, claim 1. (Ex. 1113, Hashemi Dec. 109.) See above discussion of 792 patent, claim 8; see also 1104 at 5:49-52 ( demodulators 66 include a demodulator for analog television signals 66 a, a demodulator for digital television signals 66 b and a demodulator 66 c for digital data channels. ); 6:6-7, 6:6-10, 5:45-58, 1:55-57. See above discussion of 792 patent, claim 5. Favrat (Ex. 1104), Oku (Ex. 1108), Eglit (Ex. 1110) and Wilkie (Ex. 1106) (Ex. 1113, Hashemi Dec. 111.) See, e.g., Ex. 1104, Favrat, as cited in section VI.A.1 above, with respect to claim 1. (Ex. 1113, Hashemi Dec. 112.) Ex. 1108, Oku, Fig. 2; Ex. 1108 at Figures 1, 4, 6-7, 9-17; id. at 2:59-63 ( An object of the present invention is to solve the above problems, facilitate provisions to broadcasted variety of picture formats and realize 49

a third driver circuit for driving the analog output signals from the second digital-to-analog converter onto a fourth output terminal, simultaneous reception of an analog broadcast.). (Ex. 1113, Hashemi Dec. 113.) wherein the fourth output terminal provides signals indicative of video information encoded in the input RF signal when the input RF signal has an analog television signal format. 792 Patent - Claim 23 (Ex. 1101) 23. The television receiver of claim 20, wherein the signal output circuit further comprises: a second serializer circuit coupled to receive the digital output signals from the signal processor and convert the digital output signals to a serial digital data stream; and x. 1108 at Figures 2 and 4. (Ex. 1113, Hashemi Dec. 114.) See, e.g., Ex. 1104, Favrat, as cited in section VI.A.4 above, with respect to claim 4; see also Ex. 1104 at 5:49-52 ( demodulators 66 include a demodulator for analog television signals 66 a ), 5:59-62 ( Analog demodulator 66a provides three output signals: a Composite Video Baseband Signal (CVBS) containing the video information, and audio 1 and audio 2 containing the audio information. ) Favrat (Ex. 1104), Oku (Ex. 1108), Eglit (Ex. 1110) and Wilkie (Ex. 1106) (Ex. 1113, Hashemi Dec. 115.) See, e.g., Ex. 1104, Favrat, as cited in section VI.A.1 above, with respect to claim 1. (Ex. 1113, Hashemi Dec. 116.) 50