Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7828 Filed 10/21/22 Page 1 of 13
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`EXHIBIT G
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7829 Filed 10/21/22 Page 2 of 13
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`Example Asserted Claims1 of U.S. Patent No. 8,467,366
`
`Claim 1 of the ’366 Patent
`
`Claim 17 of the ’366 Patent
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`In a multi-cell orthogonal frequency division
`multiple access (OFDMA) wireless
`communication system comprising a plurality
`of base stations and mobile stations, a mobile
`station configured to communicate with a
`serving base station in a cell via a
`communication channel, the mobile station
`comprising:
`
`In an orthogonal frequency division multiple
`access (OFDMA) wireless communication
`system, a method for signal transmission by a
`mobile station to a serving base station via a
`communication channel, the method
`comprising:
`
`an apparatus configured to transmit a data
`signal to the serving base station in the cell
`over a data subchannel, wherein the data
`subchannel comprises a plurality of adjacent
`or non-adjacent subcarriers within the
`communication channel; and
`
`transmitting a data signal over a data
`subchannel to the serving base station,
`wherein the data subchannel comprises a
`plurality of adjacent or non-adjacent
`subcarriers within the communication
`channel; and
`
`an apparatus configured to transmit a ranging
`signal to the serving base station in the cell
`over a ranging subchannel for random access,
`wherein:
`
`the ranging signal is formed from a ranging
`sequence selected from a set of ranging
`sequences associated with the cell for
`identifying the mobile station;
`
`transmitting a ranging signal over a ranging
`subchannel to the serving base station for
`random access, wherein:
`
`the ranging signal is formed from a ranging
`sequence selected from a set of ranging
`sequences for identifying the mobile station;
`
`the ranging signal lasts over a period of one or
`multiple orthogonal frequency division
`multiplexing (OFDM) symbols and the
`ranging signal exhibits a low peak-to-average
`power ratio in the time domain; and
`
`the ranging signal lasts over a period of one or
`multiple orthogonal frequency division
`multiplexing (OFDM) symbols and the
`ranging signal exhibits a low peak-to-average
`power ratio in the time domain; and
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`the ranging subchannel comprises at least one
`block of subcarriers within the
`communication channel and power levels of
`subcarriers at both ends of a block are set to
`zero.
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`the ranging subchannel comprises at least one
`block of subcarriers within the
`communication channel and power levels of
`subcarriers at both ends of a block are set to
`zero.
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`1 Neo asserts the following claims of the ’366 Patent: 1, 2, 3, 4, 5, 17, 20, 21.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7830 Filed 10/21/22 Page 3 of 13
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`Claim 4 of the ’366 Patent
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`Claim 20 of the ’366 Patent
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`The mobile station of claim 1, wherein
`subcarriers in a block are contiguous in
`frequency.
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`The method of claim 17, wherein subcarriers
`in a block are contiguous in frequency.
`
`Claim 5 of the ’366 Patent
`
`Claim 21 of the ’366 Patent
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`The mobile station of claim 1, further
`comprising an apparatus configured to control
`a transmission power of the ranging signal
`using an open-loop power control method by:
`
`The method of claim 17, further comprising
`controlling a transmission power of the
`ranging signal using an open-loop power
`control method by:
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`estimating a path loss between the serving
`base station and the mobile station based on a
`received downlink signal;
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`estimating a path loss between the serving
`base station and the mobile station based on a
`received downlink signal;
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`setting the transmission power of the ranging
`signal based on the path loss; and
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`setting the transmission power of the ranging
`signal based on the path loss; and
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`increasing the transmission power of the
`ranging signal for retransmission.
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`increasing the transmission power of the
`ranging signal for retransmission.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7831 Filed 10/21/22 Page 4 of 13
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`Example Asserted Claims2 of U.S. Patent No. 10,075,941
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`Claim 8 of the ’941 Patent
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`Claim 13 of the ’941 Patent
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`A link adaptation method by a mobile station
`served by a serving base station in an
`Orthogonal Frequency Division Multiplexing
`(OFDM) communication system, the
`communication system utilizing a
`transmission structure with time slots in the
`time domain and frequency subchannels in
`the frequency domain, the method
`comprising:
`
`A mobile station served by a serving base
`station in an Orthogonal Frequency Division
`Multiplexing (OFDM) communication
`system, the communication system utilizing a
`transmission structure with time slots in the
`time domain and frequency subchannels in
`the frequency domain, the mobile station
`comprising a receiver configured to:
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`receiving a control message from the serving
`base station over a control channel, wherein:
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`receive a control message from the serving
`base station over a control channel, wherein:
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`the control message contains transmission
`parameters specific to the mobile station for a
`subsequent transmission by the serving base
`station over a frequency subchannel to the
`mobile station in a time slot; and
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`the control message contains transmission
`parameters specific to the mobile station for a
`subsequent transmission by the serving base
`station over a frequency subchannel to the
`mobile station in a time slot; and
`
`the mobile station-specific transmission
`parameters indicate an antenna transmission
`scheme and a corresponding subchannel
`configuration, the antenna transmission
`scheme comprising a transmission diversity
`scheme or a multiple-input multiple-output
`(MIMO) scheme and the corresponding
`subchannel configuration characterized by
`distributed subcarriers or localized subcarriers
`in the frequency domain; and
`
`the mobile station-specific transmission
`parameters indicate an antenna transmission
`scheme and a corresponding subchannel
`configuration, the antenna transmission
`scheme comprising a transmission diversity
`scheme or a multiple-input multiple-output
`(MIMO) scheme and the corresponding
`subchannel configuration characterized by
`distributed subcarriers or localized subcarriers
`in the frequency domain; and
`
`receiving a data packet transmitted by the
`serving base station using the mobile station-
`specific transmission parameters over the
`frequency subchannel.
`
`receive a data packet transmitted by the
`serving base station using the mobile station-
`specific transmission parameters over the
`frequency subchannel.
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`2 Neo asserts the following claims of the ’941 Patent: 8, 10, 12, 13, 14.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7832 Filed 10/21/22 Page 5 of 13
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`Example Asserted Claims3 of U.S. Patent No. 10,447,450 Patent
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`Claim 8 of the ’450 Patent
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`Claim 10 of the ’450 Patent
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`The mobile device of claim 7, wherein the
`starting time-frequency coordinate indicates a
`starting OFDM symbol of the segment of
`time-frequency resource.
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`The mobile device of claim 7, wherein the
`starting time-frequency coordinate indicates a
`starting group of subcarriers of the segment of
`time-frequency resource.
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`3 Neo asserts the following claims of the ’450 Patent: 7, 8, 10, 11.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7833 Filed 10/21/22 Page 6 of 13
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`Example Asserted Claims4 of U.S. Patent No. 10,771,302
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`Claim 1 of the ’302 Patent
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`Claim 23 of the ’302 Patent
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`A communication method for a mobile device
`in an Orthogonal Frequency Division
`Multiplexing (OFDM) communication
`system, the method comprising:
`
`A mobile device in an Orthogonal Frequency
`Division Multiplexing (OFDM)
`communication system, the mobile device
`comprising:
`
`receiving a request for a probing signal from a
`base station in the system; and
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`a receiver configured to receive a request for
`a probing signal from a base station in the
`system;
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`transmitting, in response to the received
`request, the probing signal with a code
`sequence modulated in the frequency domain,
`wherein
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`a transmitter configured to form and transmit,
`in response to the received request, the
`probing signal with a code sequence
`modulated in the frequency domain, wherein:
`
`the probing signal is configured to overlap, in
`the time domain, with uplink signals
`transmitted over an uplink frequency band by
`other mobile devices in the system; and
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`the probing signal is configured to overlap, in
`the time domain, with uplink signals
`transmitted over an uplink frequency band by
`other mobile devices in the system; and
`
`the probing signal is configured to occupy a
`portion of spectrum in the uplink frequency
`band not designated for transmission of
`uplink control signals in the system.
`
`the probing signal is configured to occupy a
`portion of spectrum in the uplink frequency
`band not designated for transmission of
`uplink control signals in the system.
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`Claim 2 of the ’302 Patent
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`Claim 24 of the ’302 Patent
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`The method of claim 1, wherein the probing
`signal provides information for the base
`station to estimate a channel profile in the
`frequency domain.
`
`The mobile device of claim 23, wherein the
`probing signal provides information for the
`base station to estimate a channel profile in
`the frequency domain.
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`4 Neo asserts the following claims of the ’302 Patent: 1, 2, 4, 5, 6, 7, 23, 24, 26, 27, 28, 29.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7834 Filed 10/21/22 Page 7 of 13
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`Claim 4 of the ’302 Patent
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`Claim 26 of the ’302 Patent
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`The method of claim 1, wherein the probing
`signal provides information for the base
`station to determine a transmission format for
`a subsequent transmission.
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`The mobile device of claim 23, wherein the
`probing signal provides information for the
`base station to determine a transmission
`format for a subsequent transmission.
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`Claim 5 of the ’302 Patent
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`Claim 27 of the ’302 Patent
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`The method of claim 4, wherein the
`transmission format comprises a
`modulation/coding or pilot pattern.
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`The mobile device of claim 26, wherein the
`transmission format comprises a
`modulation/coding or pilot pattern.
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`Claim 6 of the ’302 Patent
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`Claim 28 of the ’302 Patent
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`The method of claim 1, wherein the portion of
`spectrum is available for transmission of
`uplink data signals by other mobile devices in
`the system during a time period when the
`portion of the spectrum is not occupied by the
`probing signal.
`
`The mobile device of claim 23, wherein the
`portion of spectrum is available for
`transmission of uplink data signals by other
`mobile devices in the system during a time
`period when the portion of the spectrum is not
`occupied by the probing signal.
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`
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`Claim 7 of the ’302 Patent
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`Claim 29 of the ’302 Patent
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`The method of claim 1, wherein the portion of
`spectrum is within a center portion of the
`uplink frequency band and subcarriers for the
`transmission of uplink control signals are
`within an outer portion of the uplink
`frequency band.
`
`The mobile device of claim 23, wherein the
`portion of spectrum is within a center portion
`of the uplink frequency band and subcarriers
`for the transmission of uplink control signals
`are within an outer portion of the uplink
`frequency band.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7835 Filed 10/21/22 Page 8 of 13
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`Example Asserted Claims5 of U.S. Patent No. 10,833,908
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`Claim 1 of the ’908 Patent
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`Claim 11 of the ’908 Patent
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`A mobile station comprising:
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`A method performed by a mobile station, the
`method comprising:
`
`a transmitter configured to:
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`
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`transmit, to a base station, a first uplink signal
`within a frequency band, wherein the first
`uplink signal is an orthogonal frequency
`division multiplexing (OFDM) signal and
`utilizes a frame format comprising a plurality
`of timeslots, each timeslot comprising a
`plurality of OFDM symbols;
`
`transmitting, to a base station, a first uplink
`signal within a frequency band, wherein the
`first uplink signal is an orthogonal frequency
`division multiplexing (OFDM) signal and
`utilizes a frame format comprising a plurality
`of timeslots, each timeslot comprising a
`plurality of OFDM symbols;
`
`transmit, to the base station, a random access
`signal followed by a guard period in only a
`portion of the frequency band, wherein the
`random access signal includes a sequence
`associated with the base station, wherein a
`time duration of a combination of the random
`access signal and the guard period is greater
`than a time duration of at least one of the
`plurality of OFDM symbols; and
`
`transmitting, to the base station, an random
`access signal followed by a guard period in
`only a portion of the frequency band, wherein
`the random access signal includes a sequence
`associated with the base station, wherein a
`time duration of a combination of the random
`access signal and the guard period is greater
`than a time duration of at least one of the
`plurality of OFDM symbols; and
`
`a receiver configured to receive, from the
`base station, a response message.
`
`receiving, from the base station, a response
`message.
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`Claim 2 of the ’908 Patent
`
`Claim 12 of the ’908 Patent Claim 22 of the ’908 Patent
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`The mobile station of claim 1,
`wherein: the receiver is
`configured to determine if the
`response message identifies
`the sequence associated with
`the base station in the random
`access signal; and
`
`The method claim 11, further
`comprising: determining if
`the response message
`identifies the sequence
`associated with the base
`station in the random access
`signal; and
`
`The mobile station of claim
`21, wherein: the receiver
`circuit is configured to
`determine if the response
`message identifies the
`sequence associated with the
`base station in the random
`access signal; and
`
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`5 Neo asserts the following claims of the ’908 Patent: 1-30.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7836 Filed 10/21/22 Page 9 of 13
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`on a condition that the
`response message identifies
`the sequence associated with
`the base station in the random
`access signal, the transmitter
`is configured to transmit a
`second uplink signal.
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`on a condition that the
`response message identifies
`the sequence associated with
`the base station in the random
`access signal, transmitting a
`second uplink signal.
`
`on a condition that the
`response message identifies
`the sequence associated with
`the base station in the random
`access signal, the first type of
`transmitter signal processing
`circuit is configured to
`transmit a second uplink
`signal.
`
`Claim 3 of the ’908 Patent
`
`Claim 13 of the ’908 Patent Claim 23 of the ’908 Patent
`
`The mobile station of claim 2,
`wherein the response message
`includes power adjustment
`information and wherein the
`transmitter is configured to
`transmit the second uplink
`signal according to the power
`adjustment information.
`
`The method of claim 12,
`wherein the response message
`includes power adjustment
`information and wherein the
`second uplink signal is
`transmitted according to the
`power adjustment
`information.
`
`The mobile station of claim
`22, wherein the response
`message includes power
`adjustment information and
`wherein the first type of
`transmitter signal processing
`circuit is configured to
`transmit the second uplink
`signal according to the power
`adjustment information.
`
`Claim 4 of the ’908 Patent
`
`Claim 14 of the ’908 Patent Claim 24 of the ’908 Patent
`
`The mobile station of claim 1,
`wherein the portion of the
`frequency band used for
`transmission of the random
`access signal does not include
`control channels.
`
`The method of claim 11,
`wherein the portion of the
`frequency band used for
`transmission of the random
`access signal does not include
`control channels.
`
`The mobile station of claim
`21, wherein the portion of the
`frequency band used for
`transmission of the random
`access signal does not include
`control channels.
`
`Claim 5 of the ’908 Patent
`
`Claim 15 of the ’908 Patent Claim 25 of the ’908 Patent
`
`The mobile station of claim 1,
`wherein the response message
`includes a mobile station
`identifier assigned to the
`mobile station.
`
`The method of claim 11,
`wherein the response message
`includes a mobile station
`identifier assigned to the
`mobile station.
`
`The mobile station of claim
`21, wherein the response
`message includes a mobile
`station identifier assigned to
`the mobile station.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7837 Filed 10/21/22 Page 10 of 13
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`Claim 6 of the ’908 Patent
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`Claim 16 of the ’908 Patent Claim 26 of the ’908 Patent
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`The mobile station of claim 1,
`wherein the time duration of
`the combination of the
`random access signal and the
`guard period is greater than a
`time duration of at least two
`of the plurality of OFDM
`symbols.
`
`The method of claim 11,
`wherein the time duration of
`the combination of the
`random access signal and the
`guard period is greater than a
`time duration of at least two
`of the plurality of OFDM
`symbols.
`
`The mobile station of claim
`21, wherein the time duration
`of the combination of the
`random access signal and the
`guard period is greater than a
`time duration of at least two
`of the plurality of OFDM
`symbols.
`
`Claim 7 of the ’908 Patent
`
`Claim 17 of the ’908 Patent Claim 27 of the ’908 Patent
`
`The mobile station of claim 1,
`wherein the frequency band
`includes an outer portion and
`a center portion, wherein the
`portion of the frequency band
`for the random access signal
`is in the center portion and
`uplink control signals are sent
`in the outer portion.
`
`The method of claim 11,
`wherein the frequency band
`includes an outer portion and
`a center portion, wherein the
`portion of the frequency band
`for the random access signal
`is in the center portion and
`uplink control signals are sent
`in the outer portion.
`
`The mobile station of claim
`21, wherein the frequency
`band includes an outer
`portion and a center portion,
`wherein the portion of the
`frequency band for the
`random access signal is in the
`center portion and uplink
`control signals are sent in the
`outer portion.
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`Claim 8 of the ’908 Patent
`
`Claim 18 of the ’908 Patent Claim 28 of the ’908 Patent
`
`The mobile station of claim 1,
`wherein the random access
`signal is a spread spectrum
`signal.
`
`The method of claim 11,
`wherein the random access
`signal is a spread spectrum
`signal.
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`The mobile station of claim
`21, wherein the random
`access signal is a spread
`spectrum signal.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7838 Filed 10/21/22 Page 11 of 13
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`Claim 9 of the ’908 Patent
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`Claim 19 of the ’908 Patent Claim 29 of the ’908 Patent
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`The mobile station of claim 1,
`wherein: the receiver is
`further configured to receive
`broadcast information from
`the base station, the broadcast
`information indicating at least
`one sequence associated with
`the base station for use in
`producing the random access
`signal.
`
`The method of claim 11,
`further comprising: receiving
`broadcast information from
`the base station, the broadcast
`information indicating at least
`one sequence associated with
`the base station for use in
`producing the random access
`signal.
`
`The mobile station of claim
`21, wherein: the receiver
`circuit is further configured to
`receive broadcast information
`from the base station, the
`broadcast information
`indicating at least one
`sequence associated with the
`base station for use in
`producing the random access
`signal.
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`Claim 10 of the ’908 Patent Claim 20 of the ’908 Patent Claim 30 of the ’908 Patent
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`The mobile station of claim 1,
`wherein the transmitter
`includes an OFDM
`transmitter signal processing
`circuit comprising: a serial to
`parallel converter, an inverse
`Fourier transform, and a
`cyclic prefix addition circuit;
`and
`
`The method of claim 11,
`wherein the first uplink signal
`is provided by an OFDM
`transmitter signal processing
`circuit comprising: a serial to
`parallel converter, an inverse
`Fourier transform, and a
`cyclic prefix addition circuit.
`
`the OFDM transmitter signal
`processing circuit outputs the
`first uplink signal.
`
`
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`The mobile station of claim
`21, wherein: the first type of
`transmitter signal processing
`circuit is an OFDM
`transmitter signal processing
`circuit comprising: a serial to
`parallel converter, an inverse
`Fourier transform, and a
`cyclic prefix addition circuit;
`and
`
`the OFDM transmitter signal
`processing circuit outputs the
`first uplink signal.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7839 Filed 10/21/22 Page 12 of 13
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`Example Asserted Claims6 of U.S. Patent No. 10,965,512
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`Claim 15 of the ’512 Patent
`
`Claim 23 of the ’512 Patent
`
`An orthogonal frequency division multiple
`access (OFDMA)-compatible mobile station
`that uses subcarriers in a frequency domain
`and time slots in a time domain, the OFDMA-
`compatible mobile station comprising:
`
`A method performed by an orthogonal
`frequency division multiple access
`(OFDMA)-compatible mobile station that
`uses subcarriers in a frequency domain and
`time slots in a time domain, the method
`comprising:
`
`At least one antenna; and
`
`A receiver; and
`
`The at least one antenna and the receiver are
`configured to:
`
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`receive first pilots of a first type on a first
`plurality of subcarriers, wherein the first
`pilots are cell-specific pilots; and
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`receiving first pilots of a first type on a first
`plurality of subcarriers, wherein the first
`pilots are cell-specific pilots;
`
`receive second pilots of a second type and
`data on a second plurality of subcarriers,
`wherein the first plurality of subcarriers and
`the second plurality of subcarriers are
`received in at least one of the time slots;
`
`receiving second pilots of a second type and
`data on a second plurality of subcarriers,
`wherein the first plurality of subcarriers and
`the second plurality of subcarriers are
`received in at least one of the time slots;
`
`wherein at least some subcarriers of the first
`plurality of subcarriers or the second plurality
`of subcarriers are beam-formed; and
`
`wherein at least some subcarriers of the first
`plurality of subcarriers or the second plurality
`of subcarriers are beam-formed;
`
`the receiver is further configured to: recover
`the data using channel estimates from at least
`the second pilots; and
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`recover cell-specific information using the
`cell-specific pilots;
`
`recovering the data using channel estimates
`from at least the second pilots; and
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`recovering cell-specific information using the
`cell-specific pilots;
`
`wherein the second type is different than the
`first type and wherein the first pilots do not
`interfere with the second pilots.
`
`wherein the second type is different than the
`first type and wherein the first pilots do not
`interfere with the second pilots.
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`6 Neo asserts the following claims of the ’512 Patent: 15, 20, 21, 23, 28, 29.
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`Case 2:22-md-03034-TGB ECF No. 96-8, PageID.7840 Filed 10/21/22 Page 13 of 13
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`Claim 20 of the ’512 Patent
`
`Claim 28 of the ’512 Patent
`
`The OFDMA-compatible mobile station of
`claim 15 wherein the second plurality of
`subcarriers are beam-formed.
`
`The method of claim 23 wherein the second
`plurality of subcarriers are beam-formed.
`
`Claim 21 of the ’512 Patent
`
`Claim 29 of the ’512 Patent
`
`The OFDMA-compatible mobile station of
`claim 15 wherein the first plurality of
`subcarriers are not aligned in frequency with
`subcarriers of at least another cell onto which
`respective cell-specific pilots are inserted.
`
`The method of claim 23 wherein the first
`plurality of subcarriers are not aligned in
`frequency with subcarriers of at least another
`cell onto which respective cell-specific pilots
`are inserted.
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