Difference between revisions of "Aufgaben:Exercise 3.4: Different Voice Codecs"
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| − | [[File:P_ID2221__Mob_A_3_4.png|right|frame|Audiosignale von | + | [[File:P_ID2221__Mob_A_3_4.png|right|frame|Audiosignale von "Narrow–Band" <br>und "Wide–Band"]] |
The development of the GSM standard after 1990 was accompanied by the standardization of various voice codecs: | The development of the GSM standard after 1990 was accompanied by the standardization of various voice codecs: | ||
| − | *With the first "Full | + | *With the first "Full Rate Codec" $\rm (FR)$ from 1991 a reduction to the data rate $13 \ \rm kbit/s$ was achieved, sufficiently low to be able to transmit a speech signal over a single traffic channel. |
| − | *In 1994 the "Half | + | *In 1994 the "Half Rate Codec" $\rm (HR)$ with the bitrate $5.6 \ \rm kbit/s$ was developed with the aim of being able to transmit two calls simultaneously in one traffic channel if required. However, the quality does not quite reach the full rate codec. |
| − | *The "Enhanced Full | + | *The "Enhanced Full Rate Codec" $\rm (EFR)$ from 1995 represented a significant development based on the data reduction method $\rm ACELP$ ("Algebraic Code Excited Linear Prediction"). The EFR codec delivers a data rate of $12.2 \ \rm kbit/s$ and stands for the common quality standard in mobile communications nowadays. |
| − | *In 1999, ETSI standardized the Adaptive Multi | + | *In 1999, ETSI standardized the Adaptive Multi Rate Codec" $\rm (AMR)$ for GSM. This provides eight different modes with data rates between $4.75 \ \ \rm kbit/s$ and $12.2 \ \ \rm kbit/s$ . The AMR codec uses the ACELP method like the EFR codec. |
*The "Wideband AMR" $\rm(WB-AMR)$ is a further development of the original AMR. It was standardized by the 3GPP consortium in 2001 and by ITU-T in 2002 and uses the frequency range from $50 \ \rm Hz$ to $7 \rm kHz$. This corresponds to a "'''W'''ide'''B'''and signal". | *The "Wideband AMR" $\rm(WB-AMR)$ is a further development of the original AMR. It was standardized by the 3GPP consortium in 2001 and by ITU-T in 2002 and uses the frequency range from $50 \ \rm Hz$ to $7 \rm kHz$. This corresponds to a "'''W'''ide'''B'''and signal". | ||
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'''(2)''' Correct are the <u>answers 2 and 3</u>: | '''(2)''' Correct are the <u>answers 2 and 3</u>: | ||
| − | *The EFR codec from 1995 is a significant development of the "Full | + | *The EFR codec from 1995 is a significant development of the "Full Rate Codecs" from 1991, whereby, among other things, speech quality is less impaired by background noise. |
| − | *Like the AMR, the EFR codec is based on the data reduction method ACELP ( | + | *Like the AMR, the EFR codec is based on the data reduction method ACELP ("Algebraic Code Excited Linear Prediction"). |
*The first proposed solution is wrong. Like the FR and AMR codecs, the EFR codec is only designed for the telephone channel $(300 \ \rm Hz$ – $3.4 \ \rm kHz)$. | *The first proposed solution is wrong. Like the FR and AMR codecs, the EFR codec is only designed for the telephone channel $(300 \ \rm Hz$ – $3.4 \ \rm kHz)$. | ||
*For better intelligibility and to avoid a dull sound, there is also a mid-range boost and a low-frequency cut. | *For better intelligibility and to avoid a dull sound, there is also a mid-range boost and a low-frequency cut. | ||
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*The advantage of the AMR codec over the EFR is its greater flexibility. | *The advantage of the AMR codec over the EFR is its greater flexibility. | ||
*If the channel quality deteriorates significantly, it is possible to switch smoothly to a low-rate mode where transmission errors are less disturbing. | *If the channel quality deteriorates significantly, it is possible to switch smoothly to a low-rate mode where transmission errors are less disturbing. | ||
| − | *In addition, as with the "Half | + | *In addition, as with the "Half Rate Codec", it is possible to have two conversations in one traffic channel. |
*The highest mode at $\rm 12.2 \ kbit/s$ - and not the lowest - is identical to the EFR codec. It is therefore obvious that AMR cannot provide better voice quality than EFR. | *The highest mode at $\rm 12.2 \ kbit/s$ - and not the lowest - is identical to the EFR codec. It is therefore obvious that AMR cannot provide better voice quality than EFR. | ||
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'''(4)''' <u>All answers are correct</u>: | '''(4)''' <u>All answers are correct</u>: | ||
*Nine modes are provided in wideband–AMR, but only five of them are used for mobile communications, namely those with data rates of $6.60$, $8.85$, $12.65$, $15.85$, and $\text{23.65 kbit/s}$. | *Nine modes are provided in wideband–AMR, but only five of them are used for mobile communications, namely those with data rates of $6.60$, $8.85$, $12.65$, $15.85$, and $\text{23.65 kbit/s}$. | ||
| − | *The modes up to $\text{12.65 kbit/s}$ have the advantage that a | + | *The modes up to $\text{12.65 kbit/s}$ have the advantage that a speech signal encoded in this way can be accommodated in a single GSM traffic channel. For the higher rate modes, GSM/EDGE or UMTS is required. |
*The higher rate modes $(15.85$ and $\text{23.65 kbit/s})$ provide only a slight improvement for speech, but due to the larger frequency range, they provide a noticeable improvement for the transmission of music. | *The higher rate modes $(15.85$ and $\text{23.65 kbit/s})$ provide only a slight improvement for speech, but due to the larger frequency range, they provide a noticeable improvement for the transmission of music. | ||
*Both the wideband AMR and the higher modes of narrowband AMR show weaknesses here. An even lower data rate gives extremely poor results with music signals. | *Both the wideband AMR and the higher modes of narrowband AMR show weaknesses here. An even lower data rate gives extremely poor results with music signals. | ||
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| − | [[Category: | + | [[Category:Mobile Communications: Exercises|^3.2 Similarities between GSM and UMTS |
^]] | ^]] | ||
Latest revision as of 13:28, 23 January 2023
Audiosignale von "Narrow–Band"
und "Wide–Band"
und "Wide–Band"
The development of the GSM standard after 1990 was accompanied by the standardization of various voice codecs:
- With the first "Full Rate Codec" $\rm (FR)$ from 1991 a reduction to the data rate $13 \ \rm kbit/s$ was achieved, sufficiently low to be able to transmit a speech signal over a single traffic channel.
- In 1994 the "Half Rate Codec" $\rm (HR)$ with the bitrate $5.6 \ \rm kbit/s$ was developed with the aim of being able to transmit two calls simultaneously in one traffic channel if required. However, the quality does not quite reach the full rate codec.
- The "Enhanced Full Rate Codec" $\rm (EFR)$ from 1995 represented a significant development based on the data reduction method $\rm ACELP$ ("Algebraic Code Excited Linear Prediction"). The EFR codec delivers a data rate of $12.2 \ \rm kbit/s$ and stands for the common quality standard in mobile communications nowadays.
- In 1999, ETSI standardized the Adaptive Multi Rate Codec" $\rm (AMR)$ for GSM. This provides eight different modes with data rates between $4.75 \ \ \rm kbit/s$ and $12.2 \ \ \rm kbit/s$ . The AMR codec uses the ACELP method like the EFR codec.
- The "Wideband AMR" $\rm(WB-AMR)$ is a further development of the original AMR. It was standardized by the 3GPP consortium in 2001 and by ITU-T in 2002 and uses the frequency range from $50 \ \rm Hz$ to $7 \rm kHz$. This corresponds to a "WideBand signal".
Notes:
- The task belongs to the chapter Similarities between GSM and UMTS.
- The graph shows the magnitude spectrum of an audio signal and defines the characteristics "narrowband" and "wideband".
- We refer you to the interactive SWF applet Qualität verschiedener Sprachcodecs ⇒ Quality of different voice codecs
(based on "Shock Wave Flash", German language).
Questionnaire
Solution
(1) Correct are the answers 1 and 3:
- The required data rate is reduced by removing redundancy and irrelevance from the data signal.
- The artificial word "codec" indicates that the same functional unit is used for both encoding and decoding.
(2) Correct are the answers 2 and 3:
- The EFR codec from 1995 is a significant development of the "Full Rate Codecs" from 1991, whereby, among other things, speech quality is less impaired by background noise.
- Like the AMR, the EFR codec is based on the data reduction method ACELP ("Algebraic Code Excited Linear Prediction").
- The first proposed solution is wrong. Like the FR and AMR codecs, the EFR codec is only designed for the telephone channel $(300 \ \rm Hz$ – $3.4 \ \rm kHz)$.
- For better intelligibility and to avoid a dull sound, there is also a mid-range boost and a low-frequency cut.
(3) Only the answers 2 is correct:
- The advantage of the AMR codec over the EFR is its greater flexibility.
- If the channel quality deteriorates significantly, it is possible to switch smoothly to a low-rate mode where transmission errors are less disturbing.
- In addition, as with the "Half Rate Codec", it is possible to have two conversations in one traffic channel.
- The highest mode at $\rm 12.2 \ kbit/s$ - and not the lowest - is identical to the EFR codec. It is therefore obvious that AMR cannot provide better voice quality than EFR.
(4) All answers are correct:
- Nine modes are provided in wideband–AMR, but only five of them are used for mobile communications, namely those with data rates of $6.60$, $8.85$, $12.65$, $15.85$, and $\text{23.65 kbit/s}$.
- The modes up to $\text{12.65 kbit/s}$ have the advantage that a speech signal encoded in this way can be accommodated in a single GSM traffic channel. For the higher rate modes, GSM/EDGE or UMTS is required.
- The higher rate modes $(15.85$ and $\text{23.65 kbit/s})$ provide only a slight improvement for speech, but due to the larger frequency range, they provide a noticeable improvement for the transmission of music.
- Both the wideband AMR and the higher modes of narrowband AMR show weaknesses here. An even lower data rate gives extremely poor results with music signals.
- The WB-AMR has a better voice quality than the NB-AMR with a comparable data rate $\text{(12.65 kbit/s)}$. Due to the greater bandwidth, speech sounds are more natural and sibilants such as "s", "f" and "sch" become more intelligible.
