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Description  |
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BACKGROUND OF THE INVENTION
I. Field of the Invention
The present invention relates generally to communication systems and
particularly to power control in a code division multiple access
communication system.
II. Description of the Related Art
The Federal Communications Commission (FCC) governs the use of the radio
frequency (RF) spectrum, deciding which industry gets certain frequencies.
Since the RF spectrum is limited, only a small portion of the spectrum can
be assigned to each industry. The assigned spectrum, therefore, must be
used efficiently in order to allow as many frequency users as possible to
have access to the spectrum.
Multiple access modulation techniques are some of the most efficient
techniques for utilizing the RF spectrum. Examples of such modulation
techniques include time division multiple access (TDMA), frequency
division multiple access (FDMA), and code division multiple access (CDMA).
CDMA modulation employs a spread spectrum technique for the transmission of
information. A spread spectrum system uses a modulation technique that
spreads the transmitted signal over a wide frequency band. This frequency
band is typically substantially wider than the minimum bandwidth required
to transmit the signal. The spread spectrum technique is accomplished by
modulating each baseband data signal to be transmitted with a unique wide
band spreading code. Using this technique, a signal having a bandwidth of
only a few kilohertz can be spread over a bandwidth of more than a
megahertz. Typical examples of spread spectrum techniques can be found in
Spread Spectrum Communications, Volume i, M. K. Simon, Chap. 5, pp.
262-358.
A form of frequency diversity is obtained by spreading the transmitted
signal over a wide frequency range. Since only 200-300 kHz of a signal is
typically affected by a frequency selective fade, the remaining spectrum
of the transmitted signal is unaffected. A receiver that receives the
spread spectrum signal, therefore, will be affected less by the fade
condition.
In a CDMA-type radiotelephone system, multiple signals are transmitted
simultaneously at the same frequency. A particular receiver then
determines which signal is intended for that receiver by the unique
spreading code in the signal. The signals at that frequency without the
particular spreading code intended for that particular receiver appear to
be noise to that receiver and are ignored.
FIG. I shows a typical prior art CDMA transmitter for use on the reverse
channel of a radiotelephone system, the reverse channel being the link
from the mobile to the base station. A digital baseband signal is first
generated by a vocoder (voice encoder/decoder). The vocoder (100)
digitizes an analog voice or data signal using an encoding process such as
the Code Excited Linear Prediction (CELP) process that is well known in
the art.
The digital baseband signal is input to a convolutional encoder (101) at a
particular rate, such as 9600 bps. The encoder (101) convolutionally
encodes the input data bits into data symbols at a fixed encoding rate.
For example, the encoder (101) could encode the data bits at a fixed
encoding rate of one data bit to three data symbols such that the encoder
(101) outputs data symbols at a 28.8 ksym/s rate with a 9600 bps input
rate.
The data symbols from the encoder are input to an interleaver (102). The
interleaver (102) scrambles the symbols such that the lost symbols won't
be contiguous. Therefore, if more than one symbol is lost in the
communications channel, the error correcting code is able to recover the
information. The data symbols are input into the interleaver (102) in a
column by column matrix and output from the matrix row by row. The
interleaving takes place at the same 28.8 ksym/s data symbol rate that the
data symbols were input.
The interleaved data symbols are input to a modulator (104). The modulator
(104) derives a sequence of fixed length Walsh codes from the interleaved
data symbols. In 64-ary orthogonal code signaling, the interleaved data
symbols are grouped into sets of six to select one out of the 64
orthogonal codes to represent the set of six data symbols. These 64
orthogonal codes correspond to Walsh codes from a 64 by 64 Hadamard matrix
wherein a Walsh code is a single row or column of the matrix. The
modulator outputs a sequence of Walsh codes, corresponding to the input
data symbols at a fixed symbol rate, to one input of an XOR combinet
(107).
A pseudo random noise (PN) generator (103) uses a long PN sequence to
generate a user specific sequence of symbols. In a mobile radiotelephone
having an electronic serial number (ESN), the ESN can be exclusive-ORed
with the long PN sequence to generate the sequence, making the sequence
specific to that radiotelephone user. The long PN generator (103) inputs
and outputs data at the spreading rate of the system. The output of the PN
generator (103) is coupled to the XOR combinet (107).
The Walsh code spread symbols from the combiner (107) are next spread in
quadrature. The symbols are input to two XOR combiners (108 and 109) that
generate a pair of short PN sequences. The first combiner (108) XORs the
Walsh code spread symbols with the in-phase (I) sequence (105) while the
second combiner (109) XORs the Walsh code spread symbols with the
quadrature phase (Q) sequence (106).
The resulting I and Q channel code spread sequences are used to biphase
modulate a quadrature pair of sinusoids by driving the power level of the
pair of sinusoids. The sinusoidal output signals are then summed, bandpass
filtered, translated to an RF frequency, amplified, filtered, and radiated
by an antenna.
The typical prior art CDMA transmitter used on the forward channel of a
radiotelephone system, the link from the base station to the mobile, is
similar to the reverse channel. This transmitter is illustrated in FIG. 4.
The difference between the forward and reverse channel transmitters is the
addition of a Walsh code generator (401) and power control bit multiplexer
(420) between the PN generator combiner (103) and the quadrature spreading
combiners (108 and 109) for the forward channel transmitter.
The power control bit multiplexer (420) multiplexes a power control bit in
place of another bit in the frame. The mobile knows the location of this
bit and looks for this power control bit at that location. As an example,
a "0" bit instructs the mobile to increase its mean output power level a
predetermined amount and a "1" bit instructs the mobile to decrease its
mean output level a predetermined amount.
The code division channel selection generator (401) is coupled to a
combiner (402) and provides a particular Walsh code to the combiner (402).
The generator (401) provides one of 64 orthogonal codes corresponding to
64 Walsh codes from a 64 by 64 Hadamard matrix wherein a Walsh code is a
single row or column of the matrix. The combiner (402) uses the particular
Walsh code input by the code division channel generator (401) to spread
the input scrambled data symbols into Walsh code spread data symbols. The
Walsh code spread data symbols are output from the XOR combiner (402) and
into the quadrature spreading combiners at a fixed chip rate of 1.2288
Mchp/s.
The mobile can aid the base station in the control of the power on the
forward channel by transmitting a power control message to the base
station on the reverse link. The mobile gathers statistics on its error
performance and informs the base station via the power control message.
The base station may then adjust its power to the specific user
accordingly.
The problem with the type of power control described above is that, for the
forward link control, the power control message replaces voice or data
bits, thereby reducing the quality of the voice or the data throughput.
This fundamentally limits the rate at which mobile stations can send power
control messages to the base station and in turn the rate at which the
base station can adjust the output power to this specific mobile. A high
update rate transmit power adjustment would allow the base station to tune
the transmit power to each individual mobile station to a minimum level
necessary to maintain a link of a specified quality. By minimizing each
individual transmit power, the total interference generated is also
minimized, thus improving the capacity of the system. There is a resulting
need for updating the power output of a transmitter at a higher rate
without substantially degrading the quality of the data in the
transmission.
SUMMARY OF THE INVENTION
The process of the present invention enables a transmitter to update the
power output to each mobile station to which it is communicating on a
frame by frame basis. The process is accomplished through a feedback
mechanism from the mobile station to the base station. Through the
feedback mechanism, the mobile station informs the base station on whether
it is receiving frames correctly or incorrectly by including such
information on every frame of data transmitted to the base station.
The process first determines whether the power output of the transmitter,
with which communication is established, is to be increased or decreased.
The process then informs that transmitter to change its power accordingly
by including power control bits in each frame of data transmitted.
Another embodiment of the process of the present invention enables a
communication link to have a higher data rate input signal while
maintaining a constant data rate output signal. The method first
convolutionally encodes the input data signal to produce a plurality of
convolutionally encoded signals. Each of the convolutionally encoded
signals are comprised of a plurality of data symbols. Each data symbol is
repeated a predetermined number of times to produce a code repetition data
sequence at a predetermined and fixed rate. The data sequence is then
punctured such that symbols in predetermined locations of the data
sequence are deleted thus generating a data sequence at a predetermined
and fixed rate which is lower than that of the original data sequence. The
encoded signals with the repeated data symbols are multiplexed to produce
a data sequence.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows a typical prior art CDMA, reverse link transmitter for use in
a radiotelephone system.
FIG. 2 shows the forward communication link process of the present
invention as used in a CDMA radiotelephone system.
FIG. 3 shows the mobile radio process of the present invention as used in a
CDMA radiotelephone system.
FIG. 4 shows a typical prior art CDMA, forward link transmitter for use in
a radiotelephone system.
FIG. 5 shows the forward link power control process of the present
invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The variable data rate communication link process of the present invention
enables the data rate of a signal input to a convolutional encoder to be
variable without changing the data rate of the encoded signal. This
enables a higher quality voice channel or a faster facsimile or data
channel to be used without increasing the fixed output rate of 19.2 kbps.
The variable data rate is obtained by puncturing a rate 1/2 convolutional
code to obtain a rate 3/4 convolutional code. For example, a fixed input
data rate of 9600 bps encoded by a rate 1/2 convolutional code produces a
fixed output data rate of 9600.multidot.2=19.2 kbps. Equivalently, a fixed
input data rate of 14400 bps encoded by a rate 3/4 convolutional code
produces a fixed output data rate of 14400.multidot.4/3=19.2 kbps.
The forward communication link process of the present invention is
illustrated in FIG. 2. The process begins with a data signal, I(D), being
input to the convolutional encoder (201). The process enables the data
rate of this signal to be variable and as high as 14.4 kbps. The
convolutional encoder (201), in the preferred embodiment, is a rate 1/2
encoder.
The convolutional code has the generating polynomials G.sub.1 =753 and
G.sub.2 =561. In polynomial notation, the generating polynomials appear
as:
G.sub.1 (D)=1+D+D.sup.2 +D.sup.3 +D.sup.5 +D.sup.7 +D.sup.8
G.sub.2 (D)=1+D.sup.2 +D.sup.3 +D.sup.4 +D.sup.8
Since this is a rate 1/2 encoder (201), for every one bit input to the
encoder (201), two symbols will be output. By way of example, if the input
signal is comprised of bits b.sub.0, b.sub.1, and b.sub.2, the output
symbol sequences are: C.sub.11, C.sub.12, C.sub.13, C.sub.14, C.sub.15,
C.sub.16 . . . for G.sub.1 and C.sub.21, C.sub.22, C.sub.23, C.sub.24,
C.sub.25, C.sub.26 . . . for G.sub.2. Therefore, without the process of
the present invention, the input must be 9.6 kbps in order to maintain the
standard 19.2 kbps output of the rate 1/2 encoder.
The next step of the process inserts a repeat (202 and 203) of each of the
output symbols into the symbol sequence. The data rate is set by the
speech encoder or by the data service controller so it knows how many
symbol repeats need to be inserted to obtain the proper data rate. In the
preferred embodiment, the symbols are repeated once so that the output
symbol sequences are:
C.sub.11, C.sub.11, C.sub.12, C.sub.12, C.sub.13, C.sub.13, C.sub.14,
C.sub.14, C.sub.15, C.sub.15, C.sub.16, C.sub.16 . . . for G.sub.1
and
C.sub.21, C.sub.21, C.sub.22, C.sub.22, C.sub.23, C.sub.23, C.sub.24,
C.sub.24, C.sub.25, C.sub.25, C.sub.26, C.sub.26 . . . for G.sub.2.
A parallel to serial conversion is performed on these symbol sequences by a
multiplexer (204). The two symbol sequences are input to the multiplexer
(204) at a 14.4 kbps rate and are output from the multiplexer as a single
sequence having a data rate of 28.8 kbps. This multiplexing step generates
the symbol sequence:
C.sub.11, C.sub.21, C.sub.11, C.sub.21, C.sub.12, C.sub.22, C.sub.12,
C.sub.22, C.sub.13, C.sub.23, C.sub.13, C.sub.23, C.sub.14, C.sub.24,
C.sub.14, C.sub.24, C.sub.15, C.sub.25, C.sub.15, C.sub.25, C.sub.16,
C.sub.26, C.sub.16, C.sub.26 . . .
This sequence is then punctured (205) using 110101 as the puncturing
pattern, each 0 being the punctured bit. This pattern is implemented by
deleting from the symbol sequence all bits that are in locations 6n+3 and
6n+5, where n is an integer in the range of 0 to .infin.. Alternate
embodiments can puncture the symbol sequence in different locations and at
a different rate. The result of this operation is the following symbol
sequence:
C.sub.11, C.sub.21, C.sub.21, C.sub.22, C.sub.12, C.sub.22, C.sub.23,
C.sub.23, C.sub.14, C.sub.24, C.sub.24, C.sub.25, C.sub.15, C.sub.25,
C.sub.26, C.sub.26 . . .
The symbols are then input into a block interleaver (207). It will be
appreciated by those skilled in the art that other types of interleaving
can be used in alternate embodiments without departing from the scope of
the present invention. The interleaved data symbols are output by the
interleaver (207) at the same data symbol rate that they were input, 19.2
kbps. The interleaved symbol sequence is input to one input of the XOR
combiner (226).
The interleaving is necessary to reduce the likelihood that a fade or
interference will cause a large gap in the data sequence. In the case in
which symbols are also repeated, losing a symbol will not necessarily
cause a total loss of data, thus providing improved performance.
A long pseudo-noise (PN) generator (220) is coupled to the other input of
the XOR combinet (226) to provide a spreading sequence to the XOR combiner
(226). The long PN generator (220) uses a long PN sequence to generate a
user specific sequence of symbols or unique user code at a fixed rate,
19.2 kbps in the preferred embodiment. In addition to providing an
identification as to which user sent the traffic channel data bits over
the communication channel, the unique user code enhances the privacy of
the communication in the communication channel by scrambling the traffic
channel data bits. The XOR combiner (226) uses the unique user code input
by long PN generator (220) to spread the input Walsh coded data symbols
into user code spread data symbols. This spreading by the XOR combiner
(226) provides a factor increase in the overall spreading of the traffic
channel data bits to data symbols. The user code spread symbols are output
from the XOR combiner (226) at a fixed chip rate, 1.228 Mchp/s in the
preferred embodiment.
The code spread symbols are input to a combiner (260) that is also coupled
to a code division channel selection generator (250) that provides a
particular length Walsh code to the combiner (260). The generator (250)
provides one of 64 orthogonal codes corresponding to 64 Walsh codes from a
64 by 64 Hadamard matrix wherein a Walsh code is a single row or column of
the matrix. The combiner (260) uses the particular Walsh code input by the
code division channel generator (250) to spread the input scrambled data
symbols into Walsh code cover data symbols. The Walsh code cover data
symbols are output from the XOR combiner (260) and into the quadrature
covering combiners (227 and 229) at a fixed chip rate of 1.2288 Mchp/s.
A pair of short PN sequences (i.e. short when compared to the long PN
sequence used by the long PN generator (220)) are generated by an
I-channel PN generator (225) and a Q-channel PN generator (228). These PN
generators (225 and 228) may generate the same or different short PN
sequences. The XOR combiners (227 and 229) further spread the input Walsh
code spread data with the short PN sequences generated by the PN I-channel
generator (225) and PN Q-channel generator (228), respectively. The
resulting I-channel code spread sequence and Q-channel code spread
sequence are used to bi-phase modulate a quadrature pair of sinusolds by
driving the power level controls of the pair of sinusolds. The sinusolds
are summed, bandpass filtered, translated to an RF frequency, amplified,
filtered and radiated by an antenna to complete transmission of the symbol
sequence on the forward communication link.
In a CDMA cellular radiotelephone system, a process is required in the
mobile radio unit to interpret the symbol sequence transmitted on the
forward communications link. This mobile unit process of the present
invention is illustrated in FIG. 3.
The mobile unit process first demodulates the received symbol sequence
(301). The demodulated signal is then input to a deinterleave process
(302) to reverse the interleaving of the forward link process. The result
of this operation is the original sequence of symbols, including the
repeated symbols, as it was input to the interleaver of the forward link
process.
The output symbol sequence is then processed to fill in the symbols that
were deleted in the forward link puncture process (303). Since the
receiving mobile has the same puncturing pattern as the base, it knows
which symbols were deleted and can therefore replace these deleted symbols
with empty spaces, also known as erasures. The output of this operation is
as follows, where E is the erasure:
C.sub.11, C.sub.21, E, C.sub.21, E, C.sub.22, C.sub.12, C.sub.22, E,
C.sub.23, E, C.sub.23, C.sub.14, C.sub.24, E, C.sub.24, E, C.sub.25,
C.sub.15, C.sub.25, E, C.sub.26, E, C.sub.26 . . .
This sequence is then input to a buffer (304) for temporary storage. The
buffer allows the Viterbi decoder to process the sequence of symbols
multiple times to determine the data rate.
The Viterbi decoder (305) also assigns a null metric to the erasure bits as
is well known in the art. The output of the Viterbi decoder is digital
data that is converted to an analog signal by a digital to analog
converter (306). The analog signal can then be used to drive a speaker
(307) in the mobile unit.
The symbols transmitted on the forward and reverse channels are formatted
into frames, each frame having a 20 millisecond length. Copending patent
application U.S. Ser. No. 07/822,164 to Padovani et al. and assigned to
the assignee of the present invention recites a more detailed explanation
of these frames. The amount of data transmitted in each frame depends on
the data rate. The frame composition for each data rate for the forward
and reverse channels is illustrated in the following table:
______________________________________
Raw # bits
CRC Tail Rsrvd Info bit
Rate
______________________________________
288 12 8 3 265 13250
144 10 8 2 124 6200
72 8 8 2 54 2700
36 6 8 2 20 1000
______________________________________
The rate listed in the table is the information bit rate. The reserved bits
for the forward and reverse channels, in the preferred embodiment, are for
signaling, power control, and future use.
The transmit power of the forward channel transmitters can be controlled on
the reverse channel by the power control process of the present invention,
illustrated in FIG. 5. The power control process will be described as
being used in the CDMA cellular radiotelephone system, but the process can
be used in other communication systems.
The selector of the land network determines the rate at which a frame is
sent to a mobile (501) and sends the frame to all base stations
communicating with that particular mobile. The selector is part of the
base station and is responsible for the call processing requirements of
the base station.
During soft hand-off, more than one base station is communicating with a
mobile. The base stations transmit the frame to the mobile (505). After
combining the data from possible multiple base stations, the mobile
determines whether the last frame (510) has been received and decoded
correctly. If the mobile correctly decoded the last frame, the mobile sets
the power control bit in the next frame (520) that is transmitted to the
base stations.
Since the selector knows the rate at which it transmitted the last frame to
the mobile and it now has feedback from the mobile on whether that frame
was correctly decoded, the selector compiles a table of statistics (525)
on the error rates that the mobile station is incurring at each rate. The
"received correctly" entries in the table are incremented only if the
reverse link frame from the mobile, containing the feedback bit, was
received and decoded correctly (515).
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TX at full
TX at 1/2 TX at 1/4 TX at 1/8
rate rate rate rate
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RX correctly
I1 J1 K1 L1
Erased I2 J2 K2 L2
Total I = J = K = L =
I1 + I2 J1 + J2 K1 + K2 L1 + L2
Error rate
I2/I J2/J K2/K L2/L
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The selector also maintains a table of predetermined target error rates T1,
T2, T3, and T4, one for each rate. If the present invention is used in a
cellular radiotelephone system, these error rates can be set by the
cellular service carrier in order to provide a specific grade of service.
The selector next calculates the following differences.
E1=I2/I-T1
E2=J2/J-T2
E3=K2/K-T3
E4=L2/L-T4.
The selector determines the power level at which the next frame is to be
transmitted by comparing to zero the respective difference just
calculated. For example, if the frame is to be transmitted at a full rate
and El>0 (530), the power level will be P.sub.nominal +P (535), where P is
a function of the value of E1 and P.sub.nominal is the power level set by
the carrier for that geographical area. If E1=0 (540), the power level
will be P.sub.nominal (545). If E1<0, the power level is P.sub.nominal P
(550). The other data rates follow the same procedure. The selector
forwards the next frame to be transmitted to the mobile to the base
stations that are communicating with the mobile. An indication of the
power level at which the frame is to be transmitted is included with this
frame.
Alternate embodiments of the present invention insert more than one repeat
of each symbol into the symbol sequence, depending on the data rate input
to the encoder. For example, if a 2.4 kbps data rate is input to the
encoder, the symbols should be repeated three more times, for a total of 4
of the same symbols, in the output sequence to maintain a 19.2 kbps output
data rate. By adding more or less repeats, the input data rate can be
varied while maintaining the output at 19.2 kbps as required by the CDMA
interim specification from the Electronic Industries Association/Telephone
Industries Association, IS-95.
Alternate embodiments may puncture first and repeat after the puncturing
process. However, the preferred embodiment doesn't destroy the symbol as
would be done if the symbols were punctured before the repeat process. By
repeating first, the repetition of the symbol still exists after the
puncture and, therefore, this information can still be transmitted.
Alternate embodiments may also require an output rate different from the
19.2 kbps required by the CDMA specification for the base station to
mobile station link. An example of such an embodiment is the mobile
station to base station link in which the specification calls for a 28800
bps rate. In this case, a 14400 bps information rate coupled with a rate
1/2 convolutional code achieves the desired rate of 14400.multidot.2=28800
bps.
By puncturing a rate 1/2 code to obtain a rate 3/4 code, the process of the
present invention enables a higher data rate to be supported by an encoder
while the output remains constant. The puncturing process and the code
symbol repetition process also enables also enables the encoder to support
variable data rates, such as 14.4, 7.2, 3.6, and 1.8 kbps, while keeping
the output of the encoder stable at 19.2 kbps by increasing the number of
repetitions of the symbols. By using the puncturing process in a
radiotelephone having the capability of operating in the CDMA
radiotelephone system, higher voice quality and faster data and facsimile
transmissions are achieved.
The fast forward power control process of the present invention enables a
mobile to instruct a base station to change its power output at a faster
rate. This process enables the mobile to send a power change command every
frame of data without degrading the voice or data quality.
The performance degradation associated with the puncturing process of a
rate 1/2 code in the base station to mobile station link is more than
compensated for by the fast forward power control process of the present
invention. The fast forward power control process of the present invention
enables a mobile to instruct the base stations to adjust their power
output at a 50 Hz rate (every frame) in comparison to rates of 0.2 Hz that
can be achieved through other signaling methods that replace complete
frames with power control information. This process enables the mobile to
send a power change request every frame of data by using a single
information bit per frame and, therefore, without degrading the voice
quality or considerably reducing the data throughput.
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