Telecommunications Aspects of UMTS

From LNTwww

Improvements regarding speech coding


In the chapter  "Global System for Mobile Communications"  $\rm (GSM)$  of this book,  several speech codecs have already been described in detail.

$\text{Reminder:}$  A speech codec is used to reduce the data rate of a digitized speech or music signal.

  1. In the process,  redundancy and irrelevance are removed from the original signal.
  2. The artificial word  "codec"  indicates that the same functional unit is used for both,  encoding and decoding.


Among others,  the  "Adaptive Multi-Rate Codec"  $\rm (AMR)$  based on  $\rm ACELP$  $($"Algebraic Code Excited Linear Prediction"$)$  was introduced, 

  • which in the frequency range from  $\text{300 Hz}$  to  $\text{3400 Hz}$ 
  • dynamically switches between eight different modes  $($single codecs$)$ 
  • of different data rate in the range of  $\text{4. 75 kbit/s}$  to  $\text{12.2 kbit/s}$.


These codecs are also supported in UMTS Release 99 and Release 4.  Compared to the earlier speech codecs  $($Full Rate,  Half Rate, Enhanced Full Rate Vocoder$)$,  they allow

  1. independence from channel conditions and network load,
  2. the ability to adapt data rates to conditions,
  3. improved flexible error protection in the event of more severe radio interference, and
  4. thereby providing better overall voice quality.


Composition of wideband AMR modes

In 2001,  the  "3rd Generation Partnership Project"  $\text{(3gpp)}$  and the  "International Telecommuncation Union"    $\text{(ITU)}$  specified the new voice codec  »Wideband AMR«  for UMTS Release 5.  This is a further development of AMR and offers

  • an extended bandwidth from  $\text{50 Hz}$  to  $\text{7 kHz}$ 
    $($sampling frequency  $\text{16 kHz})$,
  • a total of nine modes between  $\text{6.6 kbit/s}$  and  $\text{23.85 kbit/s}$ 
    $($of which only five modes are used$)$,  and
  • improved voice quality and better (more natural) sound.



$\text{Some features of wideband AMR}$ 

  1. Speech data is delivered to the codec as PCM encoded speech with  $16\hspace{0.05cm}000$  samples per second. 
  2. The speech coding is done in blocks of  $\text{20 ms}$  and the data rate is adjusted every  $\text{20 ms}$.
  3. The band  $\text{(50 Hz}$  to  $\text{7000 Hz})$  is divided into two sub-bands,  which are encoded differently to allocate more bits to the subjectively important frequencies.
  4. The upper band  $\text{(6400 Hz}$  to  $\text{7000 Hz})$  is transmitted only in the highest mode $($with  $\text{23.85 kbit/s)}$ .
  5. In all other modes,  only frequencies  $\text{50 Hz}$  to  $\text{6400 Hz}$  are considered in encoding.
  6. Wideband AMR supports  "discontinuous transmission"'  $\rm (DTX)$.  This feature means that transmission is paused during voice pauses,  reducing both mobile station power consumption and overall interference at the air interface.  This process is also known as  "Source-Controlled Rate"  $\rm (SCR)$.
  7. The  "Voice Activity Detection"  $\rm (VAD)$  determines whether speech is in progress or not and inserts a  "silence descriptor frame"  during speech pauses.
  8. The subscriber is suggested the feeling of a continuous connection by the decoder inserting synthetically generated  "comfort noise"  during speech pauses.


Application of the CDMA method to UMTS


UMTS uses the multiple access method  "Direct Sequence Code Division Multiple Access"  $\rm (DS-CDMA)$,  which has already been discussed in the  "PN modulation"  chapter  of the book "Modulation Methods".

Here follows a brief summary of this method according to the diagram describing such a system in the equivalent low-pass range and highly simplified:

CDMA transmission system for two subscribers
  • The two data signals  $q_1(t)$  and  $q_2(t)$  are supposed to use the same channel without interfering with each other. The bit duration of each is  $T_{\rm B}$.
  • Each of the data signals is multiplied by an associated spreading code   $c_1(t)$  resp.  $c_2(t)$.
  • The sum signal  $s(t) = q_1(t) · c_1(t) + q_2(t) · c_2(t)$  is formed and transmitted.
  • At the receiver,  the same spreading codes  $c_1(t)$  resp.  $c_2(t)$  are added,  thus separating the signals again.
  • Assuming orthogonal spreading codes and a small AWGN noise,  the two reconstructed signals at the receiver output are:
$$v_1(t) = q_1(t) \ \text{and} \ v_2(t) = q_2(t).$$
  • For AWGN noise signal  $n(t)$  and orthogonal spreading codes,  this does not change the error probability due to other participants.


$\text{Example1:}$  The upper graph shows three data bits   $(+1, -1, +1)$   of the rectangular signal  $q_1(t)$  from subscriber 1,  each with symbol duration  $T_{\rm B}$.

Signals at  "Direct–Sequence Spread Spectrum"
  • Here,  the symbol duration  $T_{\rm C}$  of the spreading code  $c_1(t)$   ⇒   also called  "chip duration"  is smaller by a factor  $4$.
  • The multiplication  $s_1(t) = q_1(t) · c_1(t)$  results in a chip sequence of length  $12 · T_{\rm C}$.


One recognizes from this sketch that the signal  $s_1(t)$  is of higher frequency than  $q_1(t)$.


  • This is why this modulation method is often also called  "spread spectrum".
  • The CDMA receiver reverses this  "band spreading".  We refer to this  "receiver-side band spreading"  as  "band compression".


$\text{Summarizing:}$   By applying  "Direct Sequence Code Division Multiple Access"  $\rm (DS-CDMA)$  to a data bit sequence  $q(t)$ 

  • increases the bandwidth of  $s(t) = q(t) \cdot c(t)$  by the  »spreading factor«   $J = T_{\rm B}/T_{\rm C}$  –  this is equal to the number of  "chips per bit";
  • the chip rate  $R_{\rm C}$  is greater than the bit rate  $R_{\rm B}$ by a factor  $J$;
  • the bandwidth of the entire CDMA signal is greater than the bandwidth of each user by a factor  $J$.


That is:    $\text{In UMTS, the entire bandwidth is available to each subscriber for the entire transmission duration}$.

Recall:  In GSM,  both  "Frequency Division Multiple Access"  and  "Time Division Multiple Access"  are used as multiple access methods.

  • Here,  each subscriber has only a limited frequency band  $\rm (FDMA)$,  and
  • he only has access to the channel within time slots  $\rm (TDMA)$.


Spreading codes and scrambling with UMTS


The spreading codes for UMTS should

  • be orthogonal to each other to avoid mutual interference between subscribers,
  • allow a flexible realization of different spreading factors  $J$.


⇒   The issue presented here is also illustrated by the German-language SWF applet  "OVSF codes".

$\text{Example 2:}$  An example of this is the   »orthogonal variable spreading factor«   $\rm (OVSF)$,  which provide codes of lengths from  $J = 4$  to  $J = 512$.

Chart on the OVSF code family

These can be created using a code tree, as shown in the diagram.  Here,  at each branch,  two new codes are created from one code  $C$:

  1.   $(+C \ +\hspace{-0.1cm}C)$,  and
  2.   $(+C \ -\hspace{-0.1cm}C)$.

Note that no predecessor and successor of a code may be used.

  • So in the drawn example,  eight spreading codes with spreading factor  $J = 8$  could be used.
  • Also possible are the four codes with yellow background
  • once with  $J = 2$,
  • once with  $J = 4$,  and
  • twice with  $J = 8$.


But the lower four codes with spreading factor  $J = 8$  cannot be used,  because they all start with  "$+1 \ -\hspace{-0.1cm}1$",  which is already occupied by the OVSF code with spreading factor  $J = 2$.


Additional scrambling after spreading

To obtain more spreading codes and thus be able to supply more participants,  after the band spreading with  $c(t)$ 

  • the sequence is chip-wise scrambled again with  $w(t)$, 
  • without any further spreading.


The  »scrambling code« $w(t)$  has same length and rate as the spreading code  $c(t)$.

Typical spreading and scrambling codes for UMTS

⇒   Scrambling causes the codes to lose their complete orthogonality; they are called  "quasi-orthogonal".

  • But they are characterized by a pronounced  "auto-correlation function"  $\rm (ACF)$  around zero,  which facilitates detection at the receiver.
  • Using quasi-orthogonal codes makes sense because the set of orthogonal codes is limited and scrambling allows also different userts to use the same spreading codes.


The table summarizes some data of spreading and scrambling codes.

Generator for creating Gold codes

$\text{Example 3:}$  In UMTS, so-called  »Gold codes«  are used for scrambling. The graphic from  [3gpp][1]  shows the block diagram for the circuitry generation of such codes.

  • Two different pseudonoise sequences of equal length  $($here:  $N = 18)$  are first generated in parallel using shift registers and added bitwise using  "exclusive-or"  gates.
  • In the uplink,  each mobile station has its own scrambling code and the separation of each channel is done using the same code.
  • In contrast,  in the downlink, each coverage area of a  "Node B"  has a common scrambling code

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Channel coding for UMTS


With UMTS,  the EFR- and AMR-encoded voice data pass through a two-stage error protection  $($similar to GSM$)$,  consisting of

Insertion of CRC bits and tailbits in UMTS
  1. formation of  "cyclic redundancy check bits"  $\rm (CRC)$,
  2. subsequent convolutional encoding.


However,  these methods differ from those used for GSM in that they are more flexible,  since for UMTS they have to take different data rates into account.

⇒   For  »error detection«,  eight, twelve, sixteen or  $24$  CRC bits are formed depending on the size of the transport block  $\text{(10 ms}$  or  $\text{20 ms})$,  and appended to it.

  • Eight tail bits are also inserted at the end of each frame for synchronization purposes.
  • The diagram shows a transport block of the DCH channel with  $164$  user data bits,  to which  $16$  CRC bits and eight tail bits are appended.


⇒   For  »error correction«,  UMTS uses two different methods,  depending on the data rate:

  • For low data rates,  "convolutional codes"  with code rates  $R = 1/2$   or   $R = 1/3$  are used as with GSM.  These are generated with eight memory elements of a feedback shift register  $(256$  states$)$.  The coding gain is approximately  $4.5$  to  $6$  dB with code rate  $R = 1/3$  and at low error rates.
  • For higher data rates,  one uses  "turbo codes"  of rate   $R = 1/3$.  The shift register consists here of three memory cells,  which can assume a total of eight states.  The gain of turbo codes is larger by  $2$  to  $3$  dB than by convolutional codes and depends on the number of iterations.  You need a processor with high processing power for this and there may be relatively large delays.


After channel coding,  the data is fed to an  "interleaver"  as in GSM,  in order to be able to resolve bundle errors caused by fading on the receiving side.  Finally, for  "rate matching"  of the resulting data to the physical channel,  individual bits are removed  $($"puncturing"$)$  or repeated  $($"repetition"$)$  according to a predetermined algorithm.

Error correction mechanisms in UMTS

$\text{Example 4:}$  The graph first shows the increase in bits due to a convolutional or turbo code of rate  $R =1/3$, where  the  $188$  bit time frame  $($after the CRC checksum and tail bits$)$  becomes a  $564$  bit frame.

  • Followed by a first  $($external$)$  nesting and then a second  $($internal$)$  nesting.
  • After this,  the time frame is divided into four subframes of  $141$  bits each,  and these are then matched to the physical channel by rate matching.


Frequency responses and pulse shaping for UMTS


File:UMTS image 1.png
Block diagram of the optimal Nyquist equalizer at ideal channel Korrektur

In this section, we assume the following block diagram of a binary system with ideal channel   ⇒   $H_{\rm K}(f) = 1$.

In particular, let hold:

  • The  transmit pulse filter  converts the binary  $\{0, \ 1\}$ data into physical signals. The filter is described by the frequency response  $H_{\rm S}(f)$, which is identical in shape to the spectrum of a single transmit pulse.


  • In UMTS, the receive filter  $H_{\rm E}f) = H_{\rm S}(f)$  is matched to the transmitter  (matched filter)  and the overall frequency response  $H(f) = H_{\rm S}(f) - H_{\rm E}(f)$  satisfies the  "first Nyquist criterion":
$$ H(f) = H_{\rm CRO}(f) = \left\{ \begin{array}{c} 1 \ 0 \\ \cos^2 \left( \frac {\pi \cdot (|f| - f_1)}{2 \cdot (f_2 - f_1)} \right)\end{array} \right.\quad \begin{array}{*{1}c} {\rm{f\ddot{u}r}} \rm{f\ddot{u}r}}\ {\rm else }\hspace{0.05cm}. \end{array} \begin{array}{*{20}c} |f| \le f_1, \f| \ge f_2,\ \end{array}$$

This means:   Consecutive pulses in time do not interfere with each other   ⇒   no  "Intersymbol Interference, ISI"  occur. The associated time function is:

$$h(t) = h_{\rm CRO}(t) ={\rm si}(\pi \cdot t/ T_{\rm C}) \cdot \frac{\cos(r \cdot \pi t/T_{\rm C})}{1- (2r \cdot t/T_{\rm C})^2}. $$
  • "CRO" here stands for  "Raised Cosine" .
  • The sum  $f_1 + f_2$  is equal to the inverse of the chip duration  $T_{\rm C} = 260 \ \rm ns$, so it is equal to  $3.84 \ \rm MHz$.
  • The  rolloff factor  (we stick to the designation chosen in  $\rm LNTww$  $r$, in the UMTS standard  $\alpha$  is used for this).
$$r = \frac{f_2 - f_1}{f_2 + f_1} $$
has been determined to  $r = 0.22$  for UMTS. The two corner frequencies are thus
$$f_1 = {1}/(2 T_{\rm C}) \cdot (1-r) \approx 1.5\,{\rm MHz}, \hspace{0.2cm} f_2 ={1}/(2 T_{\rm C}) \cdot (1+r) \approx 2.35\,{\rm MHz}.$$
  • The required bandwidth is  $B = 2 - f_2 = 4.7 \ \rm MHz$. Thus, there is sufficient bandwidth available for each UMTS channel with  $5 \ \rm MHz$  .


Raised cosine spectrum and impulse response

$\text{Conclusion:}$  The graph shows.

  • on the left, the (normalized) Nyquist spectrum  $H(f)$, and
  • right the corresponding Nyquist pulse  $h(t)$, whose zero crossings are equidistant in distance  $T_{\rm C}$ .


$\text{It should be noted:}$

  • The transmit filter  $H_{\rm S}(f)$  and the matched filter  $H_{\rm E}(f)$  are each  "Root Raised Cosine"  . Only the product  $H(f) = H_{\rm S}(f) - H_{\rm E}(f)$  leads to the raised cosine.
  • This also means:   The impulse responses  $h_{\rm S}(t)$  and  $h_{\rm E}(t)$  by themselves do not satisfy the first Nyquist condition. Only the combination of the two (in the time domain the convolution) leads to the desired equidistant zeros

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Modulation methods for UMTS


The modulation techniques used in UMTS can be summarized as follows:

  • In the downlink direction  (DownlinkQuaternary Phase Shift Keying  (QPSK) is used for modulation  both in FDD  and in TDD. Here, user data (DPDCH channel) and control data (DPCCH channel) are multiplexed in time.
  • With TDD  the signal is modulated in uplink direction  (Uplink)  also by means of QPSK, but not with FDD. Here, rather, a  dual binary PSK'  (English:  Dual Channel-BPSK) is used.


With  Dual-Channel BPSK  the QPSK signal space is also used, but different channels are transmitted in in-phase and quadrature components . Thus, two chips are transmitted per modulation step. The gross chip rate is therefore twice the modulation rate of  $3.84$ Mchip per second.

Modulation and pulse shaping for UMTS

$\text{Example 5:}$  The graph shows this I/Q multiplexing method, as it is also called, in the equivalent low-pass domain:

  • The spread useful data of the DPDCH channel is modulated onto the inphase component and the spread control data of the DPCCH channel is modulated onto the quadrature component and transmitted.
  • After modulation, the quadrature component is weighted by the root of the power ratio  $G$  between the two channels to minimize the influence of the power difference between  $I$  and  $Q$ .
  • Finally, the complex sum signal  $(I +{\rm j} - Q)$  is multiplied by a scrambling code that is also complex


$\text{Conclusion:}$  An advantage of dual BPSK modulation is the possibility of using  low-power amplifiers.

  • Time division multiplexing of user and control data as in  uplink  however, is not possible in  downlink .
  • One reason for this is the use of  Discontinuous Transmission  (DTX) and the associated time constraints.


Single-user receiver


The task of a CDMA receiver is to separate and reconstruct the transmitted data of the individual subscribers from the sum of the spread data streams. A distinction is made between  single-user receivers and  multi-user receivers.

In the downlink of UMTS, a  single-user receiver is always used, since in the mobile station a joint detection of all subscribers would be too costly due to the large number of active subscribers as well as the length of the scrambling codes and the asynchronous operation.

Such a receiver consists of a bank of independent correlators. Each one of the total  $J$  correlators belongs to a specific spreading sequence. The correlation is usually formed in a so-called  correlator database  by software.

Thereby one receives at the correlator output the sum of

  • the  autocorrelation function  of the spreading code and
  • the  cross-correlation function  of all other participants with the participant's own spreading code.


Single-user receiver with matched filter Korrektur

The graphic shows the simplest realization of such a receiver with matched filter.

  • The received signal  $r(t)$  is first multiplied by the spreading code  $c(t)$  of the considered subscriber, which is called  band compression  or  despreading  (yellow background).
  • Followed by convolution with the impulse response of the matched filter  (Root Raised Cosine) to maximize SNR, and sampling in bit clock  ( $T_{\rm B}$ ).
  • Finally, the threshold decision is made, which provides the sink signal  $v(t)$ and  thus the data bits of the considered subscriber.


$\text{Please note:}$ 

For the AWGN channel, the bandspread at the transmitter and the matched bandspread at the receiver have no effect on the bit error probability because of  $c(t)^2 = 1$ . As shown in  "Exercise 4.5" , even with band spreading/band compression at the optimal receiver, regardless of the degree of spreading  $J$:

$$p_{\rm B} = {\rm Q} \left( \hspace{-0.05cm} \sqrt { {2 \cdot E_{\rm B} }/{N_{\rm 0} } } \hspace{0.05cm} \right )\hspace{0.05cm}. $$

This result can be justified as follows:
The statistical properties of white noise  $n(t)$  are not changed by multiplication with the  $±1$ signal  $c(t)$ .

Rake receiver


Another receiver for single-user detection is the  rake receiver, which leads to significant improvements for a multipath channel. The diagram shows its setup for a two-way channel with 

structure of the rake receiver (shown in equivalent low-pass) Korrektur
  • a direct path with coefficient  $h_0$  and delay time  $τ_0$,
  • an echo with coefficient  $h_1$  and delay time  $τ_1$.


For simplicity, the coefficients  $h_0$  and  $h_1$  are assumed to be real here. Due to the representation in the equivalent low-pass domain, these could also be complex.

The task of the rake receiver is to concentrate the signal energies of all paths  (in this example only two)  to a single instant. It works accordingly like a  rake  for the garden.
If one applies a dirac pulse at time  $t = 0$  to the channel input, there will be three dirac pulses at the output of the rake receiver:

$$ s(t) = \delta(t) \hspace{0.3cm}\Rightarrow\hspace{0.3cm} y(t) = h_0 \cdot h_1 \cdot \delta(t - 2\tau_0) + (h_0^2 + h_1^2) \cdot \delta(t - \tau_0 - \tau_1)+ h_0 \cdot h_1 \cdot \delta(t - 2\tau_1) .$$
  • The signal energy is concentrated at the time  $τ_0 + τ_1$. Of the total four paths, two contribute (middle term).
  • The Dirac functions at  $2τ_0$  and  $2τ_1$  do cause momentum interference. However, their weights are much smaller than those of the main path.


$\text{Example 6:}$  With channel parameters  $h_0 = 0.8$  and  $h_1 = 0.6$  the main path $($with weight  $h_0)$  contains only  $0.82/(0.82 + 0.62) = 64\%$  of the total signal energy. With rake receiver and the same weights, the above equation is:

$$ y(t) = 0.48 \cdot \delta(t - 2\tau_0) + 1.0 \cdot \delta(t - \tau_0 - \tau_1)+ 0.48 \cdot \delta(t - 2\tau_1) .$$

The share of the main path in the total energy now amounts to  ${1^2}/{(1^2 + 0.48^2 + 0.48^2)} ≈ 68\%.$


Rake receivers are preferred for implementation in mobile devices, but have limited performance when there are many active participants. In a multipath channel with many  $(M)$  paths, the Rake  $M$  finger also has. The Main Finger - also called Searcher  - is responsible for identifying and ranking the individual paths of multiple propagation. It searches for the strongest paths and assigns them to other fingers along with their control information. In the process, the time and frequency synchronization of all fingers is continuously compared with the control data of the received signal.

Multi-user receiver


In a single-user receiver, only the data signal of one subscriber is decided, while all other subscriber signals are considered as additional noise. However, the error rate of such a detector will be very large if there is large  intracell interference  (many active subscribers in the considered radio cell) or  intercell interference  (highly interfering subscribers in neighboring cells).

In contrast,  multi-user receivers  make a joint decision for all active subscribers. Their characteristics can be summarized as follows:

  • A multi-user receiver does not consider the interference from other participants as noise, but also uses the information contained in the interference signals for detection.
  • The receiver is expensive to implement and the algorithms are extremely computationally intensive. It contains an extremely large correlator database followed by a common detector.
  • The multi-user receiver must know the spreading codes of all active subscribers. This requirement precludes use in the UMTS downlink (i.e., at the mobile station). In contrast, all subscriber-specific spreading codes are known a priori to the base stations, so that multi-user detection is actually used in the uplink.
  • Some detection algorithms additionally require knowledge of other signal parameters such as energies and delay times. The common detector - the heart of the receiver - is responsible for applying the appropriate detection algorithm in each case. Examples of multi-user detection are  Decorrelating Detection  and  Interference Cancellation.


Near–far problem


The near-far problem is exclusively an uplink problem, i.e., the transmission from mobile subscribers to a base station. We consider a scenario with two users at different distances from the base station according to the following graph. This can be interpreted as follows:

Scenarios for the near-far problem


  • If both mobile stations transmit with the same power, the received power of the red user  $\rm A$  at the base station is significantly smaller than that of the blue user  $\rm B$ (left scenario) due to path loss. In large macrocells, the difference can be as much as  $100 \rm dB$ . As a result, the red signal is largely obscured by the blue.


  • You can largely avoid the near-far problem if the more distant user  $\rm A$  transmits with higher power than user  $\rm B$, as indicated in the right scenario. At the base station, the received power of both mobile stations is then (almost) equal.


Note:   In an idealized system  (one-way channel, ideal A/D converters, fully linear amplifiers ) the transmitted data of the users are orthogonal to each other and one could detect the users individually even with very different received powers. This statement is true for UMTS  (multiple access:  CDMA)  as well as for the 2G system GSM  (FDMA/TDMA)  and for the 4G system LTE  (TDMA/OFDMA).

In reality, however, orthogonality is not always given due to the following reasons:

  • different receive paths   ⇒   multipath channel,
  • non-ideal characteristics of the spreading and scrambling codes in CDMA,
  • asynchrony of users in the time domain  (basic propagation delay of paths),
  • asynchrony of users in the frequency domain  (non-ideal oscillators and Doppler shift due to mobility of users).


Consequently, the users are no longer orthogonal to each other and the signal-to-noise ratio of the user to be detected with respect to the other users is not arbitrarily high. For  "GSM"  and  "LTE"  one can assume signal-to-noise ratios of  $25 \rm dB$  and more, but for UMTS (CDMA) only approx.   $15 \ \rm dB$, with high-rate data transmission rather less.


Carrier-to-interference power ratio (CIR)

The term capacity is generally understood to mean the number of available transmission channels per cell. However, since the number of subscribers is not strictly limited in UMTS, unlike in GSM, no fixed capacity can be specified here.

  • In perfect codes, the subscribers do not interfere with each other. Thus, the maximum number of users is determined solely by the spreading factor  $J$  and the available number of mutually orthogonal codes, which, however, is also limited.
  • More practical are non-perfect, only quasi-orthogonal codes. Here, the "capacity" of a radio cell is predominantly determined by the resulting interference or the  carrier-to-interference power ratio  (CIR).


Carrier-to-Interference Ratio  ("CIR") depending on the number of subscribers





As can be seen from this graph, the "CIR" depends directly on the number of active participants. The more active subscribers there are, the more interference power is generated and the smaller the "CIR" becomes.

Furthermore, this criterion, which is decisive for UMTS, also depends on the following variables:

  • the topology and user behavior (services called up),
  • the spreading factor  $J$  and the orthogonality of the spreading code used.


In order to limit the disturbing influence of the interference power on the transmission quality, there are two possible criteria:

  • Cell breathing:  If the number of active subscribers increases significantly with UMTS, the cell radius is reduced and  (because of the now fewer subscribers in the cell)  also the current interference power is lower. A less loaded neighboring cell then steps in to supply the subscribers at the edge of the reduced cell.
  • Power control:  If the total interference power within a radio cell exceeds a specified limit, the transmit power of all subscribers is reduced accordingly and/or the data rate is reduced, resulting in poorer transmission quality for all. More about this on the next page.


Power and power control in UMTS


The ratio between the signal power and the interference power is used as the controlled variable for power control in UMTS. There are differences between the FDD and TDD modes.

Power control in FDD mode

We take a closer look at  power control in FDD mode . In the diagram you can see two different control loops:

  • The  inner control loop''  controls the transmitter power based on time slots, where one power command is transmitted in each time slot. The power of the transmitter is determined and changed using the CIR estimates in the receiver and the specifications of the  Radio Network Controller  (RNC) from the outer control loop.
  • The  outer loop  controls based on $10$ millisecond duration frames. It is implemented in the RNC and is responsible for determining the set point for the inner loop.


The FDD power control sequence is as follows:

  • The RNC provides a carrier-to-interference ratio (CIR) setpoint.
  • The receiver estimates the CIR actual value and generates control commands for the transmitter.
  • The transmitter changes the transmit power according to these control commands.


The principle of  power control in TDD mode  is similar to the control presented above for FDD mode, in fact in the downlink direction they are practically identical.


$\text{Conclusion:}$  The  TDD power control  is much slower and thus less precise than in  FDD. However, fast power control is not even possible in this case, since each participant has only a fraction of the time frame available at a time

.


Link budget


When planning UMTS networks, calculating the link budget is an important step. Knowledge of the link budget is required both for dimensioning the coverage areas and for determining the capacity and quality of service requirements.

The objective of the link budget  is to calculate the  maximum cell size  considering the following criteria:

  • Type and data rate of the services,
  • topology of the environment,
  • System configuration (location and power of base stations, handover gain),
  • service requirements (availability),
  • type of mobile station (speed, power),
  • financial and economic aspects


Budget for a voice transmission channel

$\text{Example 7:}$  The calculation of the link budget is illustrated using the example of a voice transmission channel in the UMTS downlink. Regarding the exemplary numerical values, it should be noted:

  • The transmit power is  $P_{\rm S} =19 \ \rm dBm$, which corresponds to approx.  $79 \ \rm mW$ . Here, the antenna loss is considered to be  $2\ \rm dB$ .
  • The noise power  $P_{\rm R} = 5 - 10^{-11} \ \rm mW$  is the product of UMTS bandwidth and noise power density  
      ⇒   $P_{\rm R} = -103 \ \rm dBm $.
  • The interference power is  $P_{\rm I} = -99\ \rm dBm$  corresponding to  $1.25 - 10^{-10} \ \rm mW$.
  • This gives the total interference power to  $P_{\rm R+I} = P_{\rm R} + P_{\rm I} = 1.25 - 10^{-10} \ \rm mW$ 
      ⇒   $P_{\rm R+I} =- 97.5\ \rm dBm$.
  • The antenna sensitivity results in $-97.5 - 27 + 5 - 17 + 3.5 = - 133 \ \rm dBm$. A large negative value here is "good".
  • The maximum allowable path loss should be as large as possible. One gets in the example  $19 - (-133) = 152 \ \rm dB$.
  • The  link budget  includes the margin for fading and the handover gain, and in the example  is $140 \ \rm dB$.
  • The maximum cell radius can be determined from the link budget using an "empirical formula" of Okumura-Hata. It holds:
$$ {r}\ [{\rm km}] = 10^{({\rm LinkBudget}- 137)/35}= 10^{0.0857}\approx 1.22 . $$

Notes:  

  • The figure  $\rm dB$  denotes a logarithmic power figure, referenced to  $1 \rm W$.
  • In contrast  $\rm dBm$  refers to power  $1 \rm mW$.

UMTS radio resource management


The central task of  Radio Resource Management  (RRM) is the dynamic adaptation of radio transmission parameters to the current situation  (fading, mobile station movement, load, etc.)  with the aim of,

Radio Resource Management in UMTS
  • to increase transmission and subscriber capacity,
  • improve individual transmission quality, and
  • use existing radio resources economically.


The main RRM mechanisms summarized in the diagram are explained below.

Transmit power control
The  Radio Resource Management  attempts to keep the received power and thus the carrier-to-interference ratio (CIR) at the receiver constant, or at least to prevent it from falling below a specified limit.

An example of the need for power control is the  "Near-far problem", which is known to cause a disconnect.

The step size of the power control is  $1 \ \rm dB$  or  $2 \ \rm dB$, the frequency of the control commands is  $1500$  commands per second.

Regulation of data rate
UMTS allows an exchange between data rate and transmission quality, which can be realized by selecting the spreading factor. Doubling the spreading factor here corresponds to halving the data rate and increases the quality by  $3\ \rm dB$  (spreading gain).

Access control
To avoid overload situations in the overall network, a check is made before a new connection is established to see whether the necessary resources are available. If not, the new connection is rejected. This check is realized by estimating the transmission power distribution after the new connection is established.

Load control
This becomes active if an overload occurs despite access control. In this case, a handover to another Node B is initiated and - if this is not possible - the data rates of certain nodes are lowered.

Handover
Finally, radio resource management is also responsible for handover to ensure uninterrupted connections. Mobile stations are assigned to the individual radio cells on the basis of CIR measurements.


Exercises for the chapter


Aufgabe 4.5: Pseudo Noise-Modulation

Aufgabe 4.5Z: Zur Bandspreizung bei UMTS

Aufgabe 4.6: OVSF-Codes

Aufgabe 4.7: Zum Rake-Empfänger

Quellenverzeichnis

  1. 3gpp Group:  UMTS Release 6 - Technical Specification 25.213 V6.4.0,  Sept. 2005.