Summary of the invention
The invention provides a kind of method that in the T-MMB system, the T-MMB business is adopted hierarchical modulation technology, comprising:
The modulator approach of hierarchical modulation adopts 16DAPSK/32DAPSK/64DAPSK;
The field of revising among the FIG0/15 in the T-MMB system indicates whether to adopt hierarchical modulation;
Parameter when increasing new FIG data area and being used to represent hierarchical modulation;
At transmitting terminal, T-MMB is professional to isolate high priority code stream and low priority code stream through TS stream separator, two kinds of code streams are group code stream through interweaving after separately condition access control, energy dissipation, the chnnel coding respectively, shine upon according to the hierarchical information among the FIC then, and then launch by differential modulation, OFDM modulation, D/A conversion, front end to antenna;
At receiving terminal, tuner stage mainly is the snap information in work organization district and subchannel tissue district according to the information of decoding among the FIC, filters out all parameters of hierarchical modulation, according to the hierarchical modulation information that obtains each subchannel that goes to decode.If received signal is relatively good, just decode high priority code stream and low priority code stream are sent into source decoder then; If poor signal, the high priority code stream of just only decoding is sent into source decoder then;
The high priority code stream advances different subchannels with the low priority code stream, and different subchannel identifiers (SubChId) is arranged.
According to above-mentioned method, it is characterized in that further comprising: the T-MMB traffic sub channel structure that is used for indicating whether carrying out hierarchical modulation and hierarchical modulation parameter is included in FIG (fast information group) data area of the FIB (FIB) that constitutes FIC.
According to above-mentioned method, it is characterized in that further comprising: whether carry out hierarchical modulation, with the indication of modulation type (ModuType) field, originally 11 for reserving in the FIG0/15 of T-MMB system, and present 11 are used to refer in the T-MMB system and adopt hierarchical modulation technology.
According to above-mentioned method, it is characterized in that further comprising: the hierarchical modulation parameter can increase the FIG data area newly and represent.Its method for designing is: first byte of data area (data field) of newly-increased FIG is of the same type 0, and the zone of certain expansion thereafter is own to be defined; The data area is selected at least one of group that FIG type 0 expansion 15,0 expansion 30 of FIG type, 0 expansion 7 of FIG type, 0 expansion 12 of FIG type, 0 expansion 20 of FIG type, 0 expansion 23 of FIG type, 0 expansion 29 of FIG type, FIG type 3, FIG type 4 form; Use FIG type 0 expansion 23-FIG0/23 at present.
According to above-mentioned method, it is characterized in that further comprising: the hierarchical modulation parameter is indicated with HP SubChId field, LP SubChId field, ModuType field, β value field in 0 expansion 23 of FIG type.Wherein HP SubChId field is indicated the subchannel at high priority code stream place; The subchannel at LP SubChId field indication low priority code stream place.The used modulation system of ModuType field indication hierarchical modulation; The used modulation factor of β value field indication hierarchical modulation.
According to above-mentioned method, it is characterized in that further comprising: the ModuType field is indicated modulation system used when using hierarchical modulation technology in the T-MMB system in 0 expansion 23 of FIG type, specifically is meant 16DAPSK/32DAPSK/64DAPSK.Wherein the high priority code stream is expressed as quadrant on planisphere, represents with 2 bits.
According to above-mentioned method, it is characterized in that further comprising: if carry out hierarchical modulation with the indication of hierarchical modulation designator space section in 0 expansion 15 of FIG type, then in the HP SubChId field of FIG type 0 expansion 23, insert the SubChId of high priority subchannel, in LP SubChId field, insert the SubChId of low priority subchannel.
According to above-mentioned method, it is characterized in that further comprising: increase by one of TS stream separator, each 1 of newly-increased 16APSK, 32APSK, 64APSK symbol mapper.Newly-increased 16APSK symbol mapper is different with original 16APSK symbol mapper in the T-MMB system, distance adjacent 2 in adjacent 2 distance of newly-increased 16APSK adjacent quadrant on planisphere and the same quadrant not necessarily equates, and is definite by modulation factor.Distance adjacent 2 in adjacent 2 distance of newly-increased 32APSK, 64APSK adjacent quadrant on planisphere and the same quadrant also not necessarily equates, and is definite by modulation factor.
Embodiment
Now, will describe preferred embodiment of the present invention in detail.
By the professional specific implementation method of hierarchical modulation technology emission/reception T-MMB service that adopts of T-MMB is explained as follows:
FIG0/15 reserves in DAB, is used to refer to the subchannel information of new business in the T-MMB system, and its ModuType field is used to indicate modulator approach as shown in Figure 6, and its 11 field implication is reserved, and now is revised as 11 indication hierarchical modulation, and is specific as follows:
ModuType (modulation type): this 2 bit labeling is used to refer to modulation system, and is specific as follows:
b1 b0
0 0:DQPSK;
0 1:8DPSK;
1 0:16DAPSK;
11: adopt hierarchical modulation.
FIG0/23 reserves in DAB, now is used to refer to the parameter information of applying hierarchical modulation in the T-MMB system, and is as shown in Figure 7, specific as follows:
HP SubChId (subchannel identifier): this 6 bit regions is encoded to signless binary number, is used to refer to the subchannel at certain high priority code stream place.
LP SubChId (subchannel identifier): this 6 bit regions is encoded to signless binary number, is used to refer to the subchannel at certain low priority code stream place.
ModuType (modulation type): this 2 bit labeling is used to refer to modulation system, and is specific as follows:
b1 b0
0 0:16DAPSK, as shown in Figure 9
0 1:32DAPSK is as Figure 10, shown in Figure 11
1 0:64DAPSK, as shown in figure 12
11: reserve
β value (modulation factor): this 2 bit regions is encoded to signless binary number, the spacing parameter of indication hierarchical modulation.As Fig. 9, Figure 10, Figure 11, shown in Figure 12, β=θ
1/ θ
2Size definition is as follows:
b1 b0
0 0 :β=1
0 1 :β=2
1 0 :β=4
11: reserve
At transmitting terminal, in T-MMB, adopt system block diagram such as Fig. 4, shown in Figure 5 of hierarchical modulation technology.T-MMB is professional to tell high priority code stream and low priority code stream through the TS separator, the high priority code stream is put into different subchannels with the low priority code stream, insert 11 expression hierarchical modulation in the ModuType of FIG0/15 field simultaneously, insert the identifier of high priority code stream and low priority code stream place subchannel then at FIG0/23, modulator approach (supposing to choose 16DAPSK), the layering factor (supposing to select 2) etc., again through after the respective coding separately and the coded message in the snap information passage enter the transmission frame multiplexer together, be mapped to θ shown in Figure 9 when shining upon subsequently
1/ θ
2=2 planisphere, wherein the high priority code stream is mapped as phase place, as shown in FIG. the 2nd, 3, low priority then is mapped as the 1st, 4 shown in the figure, because the distance of adjacent two points of adjacent two quadrants widens, just effectively reduced the probability of high priority code stream like this in the receiving terminal erroneous judgement.Launch by antenna through differential modulation, OFDM modulation back at last.
At receiving terminal, tuner stage is according to decoding snap information (FIC), mainly is that the snap information FIG type 0 in work organization district and subchannel tissue district is expanded in 15 and indicated whether to carry out hierarchical modulation with the ModuType field.If carry out hierarchical modulation, then in 0 expansion 23 of FIG type, find out the subchannel that HP SubChId field and LP SubChId field are identified, extract the used modulation system of ModuType field indication hierarchical modulation then; The used modulation factor of β value field indication hierarchical modulation carries out differential decoding according to above-mentioned parameter then.If the signal that receives is relatively good, just decode high priority code stream and low priority code stream are sent into source decoder decodes then; If the poor signal that receives, the high priority code stream of just only decoding is sent into source decoder decodes then.
In the T-MMB system, adopt 16APSK sign map such as Fig. 9 of hierarchical modulation technology.
To each OFDM symbol, the vector (p of 4K-bit
L, n)
N=0 4K-1(p wherein
L, nReferring to ETSI EN300 401[1] the 14.4.2 joint) need be mapped to K 16APSK symbol in the following manner:
m=0,1,2,...,K-1
Wherein K is a sub-carrier number,
Φ
L, mAs shown in table 1:
Table 1 16APSK phase mapping
Φ
l,m β=1
|
Φ
l,m β=2
|
Φ
l,m β=4
|
p
l,4m+1 p
l,4m+2 p
l,4m+3 |
π/8 |
π/6 |
π2/10 |
0 0 0 |
π3/8 |
π2/6 |
π3/10 |
0 0 1 |
π5/8 |
π4/6 |
π7/10 |
0 1 1 |
π7/8 |
π5/6 |
π8/10 |
0 1 0 |
π9/8 |
π7/6 |
π12/10 |
1 1 0 |
π11/8 |
π8/6 |
π13/10 |
1 1 1 |
π13/8 |
π10/6 |
π17/10 |
1 0 1 |
π15/8 |
π11/6 |
π18/10 |
1 0 0 |
Wherein the 32APSK sign map of hierarchical modulation such as Figure 10, Figure 11, Figure 10 is that amplitude is four kinds a planisphere, Figure 11 is that amplitude is two kinds a planisphere.
See Figure 10 earlier:
To each OFDM symbol, the vector (p of 5K-bit
L, n)
N=0 5K-1(p wherein
L, nReferring to ETSI EN300 401[1] the 14.4.2 joint) need be mapped to K 32APSK symbol in the following manner:
m=0,1,2,...,K-1
Wherein K is a sub-carrier number, Φ
L, mAs shown in table 2, A
L, mAs shown in table 3:
Table 2 32APSK phase mapping
Φ
l,m β=1
|
Φ
l,m β=2
|
Φ
l,m β=4
|
p
l,5m+2 p
l,5m+3 p
l,5m+4 |
π/8 |
π/6 |
π2/10 |
0 0 0 |
π3/8 |
π2/6 |
π3/10 |
0 0 1 |
π5/8 |
π4/6 |
π7/10 |
0 1 1 |
π7/8 |
π5/6 |
π8/10 |
0 1 0 |
π9/8 |
π7/6 |
π12/10 |
1 1 0 |
π11/8 |
π8/6 |
π13/10 |
1 1 1 |
π13/8 |
π10/6 |
π17/10 |
1 0 1 |
π15/8 |
π11/6 |
π18/10 |
1 0 0 |
The mapping of table 3 amplitude
1 |
0 0 |
α |
0 1 |
α
2 |
1 1 |
α
3 |
1 0 |
See Figure 11 again:
To each OFDM symbol, the vector (p of 5K-bit
L, n)
N=0 5K-1(p wherein
L, nReferring to ETSI EN300 401[1] the 14.4.2 joint) need be mapped to K 32APSK symbol in the following manner:
m=0,l,2,...,K-1
Wherein K is a sub-carrier number,
Φ
L, mAs shown in table 4:
Table 4 32APSK phase mapping
Φ
l,m β=1
|
Φ
l,m β=2
|
Φ
l,m β=4
|
p
l,5m+1 p
l,5m+2 p
l,5m+3 p
l,5m+4 |
π/16 |
π/10 |
π2/14 |
0 0 0 0 |
π3/16 |
π2/10 |
π3/14 |
0 0 0 1 |
π5/16 |
π3/10 |
π4/14 |
0 0 1 1 |
π7/16 |
π4/10 |
π5/14 |
0 0 1 0 |
π9/16 |
π6/10 |
π9/14 |
0 1 1 0 |
π11/16 |
π7/10 |
π10/14 |
0 1 1 1 |
π13/16 |
π8/10 |
π11/14 |
0 1 0 1 |
π15/16 |
π9/10 |
π12/14 |
0 1 0 0 |
π17/16 |
π11/10 |
π16/14 |
1 1 0 0 |
π19/16 |
π12/10 |
π17/14 |
1 1 0 1 |
π21/16 |
π13/10 |
π18/14 |
1 1 1 1 |
π23/16 |
π14/10 |
π19/14 |
1 1 1 0 |
π25/16 |
π16/10 |
π23/14 |
1 0 1 0 |
π27/16 |
π17/10 |
π24/14 |
1 0 1 1 |
π29/16 |
π18/10 |
π25/14 |
1 0 0 1 |
α
3 |
π19/10 |
π26/14 |
1 0 0 0 |
The 64APSK sign map of hierarchical modulation as shown in figure 12.
To each OFDM symbol, the vector (p of 6K-bit
L, n)
N=0 6K-1Be mapped to K 64APSK symbol in the following manner:
m=0,l,2,...,K-1
Wherein K is a sub-carrier number, Φ
L, mAs shown in table 5, A
L, mAs shown in table 6.
Table 5 64APSK phase mapping
Φ
l,m β=1
|
Φ
l,m β=2
|
Φ
l,m β=4
|
p
l,6m+2 p
l,6m+3 p
l,6m+4 p
l,6m+5 |
π/16 |
π/10 |
π2/14 |
0 0 0 0 |
π3/16 |
π2/10 |
π3/14 |
0 0 0 1 |
π5/16 |
π3/10 |
π4/14 |
0 0 1 1 |
π7/16 |
π4/10 |
π5/14 |
0 0 1 0 |
π9/16 |
π6/10 |
π9/14 |
0 1 1 0 |
π11/16 |
π7/10 |
π10/14 |
0 1 1 1 |
π13/16 |
π8/10 |
π11/14 |
0 1 0 1 |
π15/16 |
π9/10 |
π12/14 |
0 1 0 0 |
π17/16 |
π11/10 |
π16/14 |
1 1 0 0 |
π19/16 |
π12/10 |
π17/14 |
1 1 0 1 |
π21/16 |
π13/10 |
π18/14 |
1 1 1 1 |
π23/16 |
π14/10 |
π19/14 |
1 1 1 0 |
π25/16 |
π16/10 |
π23/14 |
1 0 1 0 |
π27/16 |
π17/10 |
π24/14 |
1 0 1 1 |
π29/16 |
π18/10 |
π25/14 |
1 0 0 1 |
α
3 |
π19/10 |
π26/14 |
1 0 0 0 |
The mapping of table 6 amplitude
A
l,m |
p
l,6m p
l,6m+1 |
1 |
0 0 |
α |
0 1 |
α
2 |
1 1 |
α
3 |
1 0 |
2. the frequency interlacing frequency interlacing that adopts hierarchical modulation technology in the T-MMB system is that the 16APSK/32APSK/64APSK symbol is carried out the constellation point mapping according to specific order, and different transmission modes has different interlacing rules, and formula is as follows:
y
L, k=q
L, n, l=2,3,4 ..., L and k=F (n).
Specifically see ETSI EN 300 401.
3. in the T-MMB system, adopt the differential modulation of hierarchical modulation technology
Generate the PRS signal by the phase reference symbol maker,, provide fixed phase for follow-up OFDM symbol carries out differential modulation as second OFDM symbol of transmission frame.
16DAPSK is the differential amplitude modulation scheme that combines with phase place, and its amplitude and phase place are independently carried out differential modulation respectively.Its amplitude is modulated by 2 DASK, and phase place is modulated by 8DPSK.
Differential modulation is carried out on same subcarrier of two adjacent OFDM symbols, is undertaken by following formula:
l=2,3,4,…,L,
-K/2≤k≤K/2
R wherein
LThe interior ring amplitude of expression 16DAPSK; p
L-1,4k', p
L, 4kBit behind the ' expression frequency-domain-interleaving; Φ
L-1, k', Φ
L, kPhase information behind the ' expression frequency-domain-interleaving.
32DAPSK is the differential amplitude modulation scheme that combines with phase place, and its amplitude and phase place are independently carried out differential modulation respectively.As Figure 10, shown in Figure 11, be divided into two kinds of modulator approaches, a kind of is that amplitude is modulated by 4DASK, phase place is modulated by 8DPSK; Another kind is that amplitude is modulated by 2DASK, and phase place is modulated by 16DPSK.
First talk about first kind:
Differential modulation is carried out on same subcarrier of two adjacent OFDM symbols, is undertaken by following formula:
l=2,3,4,...,L,
-K/2≤k≤K/2
R wherein
LThe interior ring amplitude of expression 32DAPSK; Φ
L-1, k', Φ
L, kPhase information behind the ' expression frequency-domain-interleaving; A
L, k' as shown in table 7:
The mapping of table 7 amplitude
A
l-1,k′
|
A
l,k′ p
l-1,5k′p
l,5k′=00
|
A
l,k′ p
l-1,5k′p
1,5k′=01
|
A
l,k′ p
l-1,5k′p
l,5k′=11
|
A
l,k ′ p
l-1,5k′p
l,5k′=10
|
1 |
1 |
α |
α
2 |
α
3 |
α |
α |
α
2 |
α
3 |
1 |
α
2 |
α
2 |
α
3 |
1 |
α |
α
3 |
α
3 |
1 |
α |
α
2 |
p
L-1,5k', p
L, 5kBit behind the ' expression frequency-domain-interleaving;
Besides another kind of:
Differential modulation is carried out on same subcarrier of two adjacent OFDM symbols, is undertaken by following formula:
l=2,3,4,...,L,
-K/2≤k≤K/2
R wherein
LThe interior ring amplitude of expression 32DAPSK; p
L-1,5k', p
L, 5kBit behind the ' expression frequency-domain-interleaving; Φ
L-1, k', Φ
L, kPhase information behind the ' expression frequency-domain-interleaving.
64DAPSK also is the differential amplitude modulation scheme that combines with phase place, and its amplitude and phase place are independently carried out differential modulation respectively.Its amplitude is modulated by 4DASK, and phase place is modulated by 16DPSK.
Differential modulation is carried out on same subcarrier of two adjacent OFDM symbols, is undertaken by following formula:
l=2,3,4,...,L,
-K/2≤k≤K/2
R wherein
LThe interior ring amplitude of expression 64DAPSK; Φ
L-1, k', Φ
L, kPhase information behind the ' expression frequency-domain-interleaving; A
L, k' as shown in table 8:
The mapping of table 8 amplitude
A
l-1,k′
|
A
l,k′ p
l-1,6k′p
l,6k′=00
|
A
l,k ′ p
l-1,6k′p
l,6k′=01
|
A
1,k′ p
l-1,6k′p
1,6k′=11
|
A
l,k′ p
l-1,6k′p
l,6k′=10
|
1 |
1 |
α |
α
2 |
α
3 |
α |
α |
α
2 |
α
3 |
1 |
α
2 |
α
2 |
α
3 |
1 |
α |
α
3 |
α
3 |
1 |
α |
α
2 |
p
L-1,6k', p
L, 6kBit behind the ' expression frequency-domain-interleaving.