The
frame structures for LTE differ between the Time Division Duplex, TDD and the
Frequency Division Duplex, FDD modes as there are different requirements on
segregating the transmitted data.
There
are two types of LTE frame structure:
- Type
1:
used for the LTE FDD mode systems.
- Type
2:
used for the LTE TDD systems.
Type
1 LTE Frame Structure
The
basic type 1 LTE frame has an overall length of 10 ms. This is then divided
into a total of 20 individual slots. LTE Subframes then consist of two slots -
in other words there are ten LTE subframes within a frame.
Type 1 LTE Frame Structure
The duration of one LTE radio frame
is 10 ms. One frame is divided into 10 subframes of 1 ms each, and each
subframe is divided into two slots of 0.5 ms each. Each slot contains either
six or seven OFDM symbols, depending on the Cyclic Prefix (CP) length. The
useful symbol time is 1/15 kHz= 66.6 mircosec. Since normal CP is about 4.69
microsec long, seven OFDM symbols can be placed in the 0.5-ms slot as each
symbol occupies (66.6 + 4.69) = 71.29 microseconds. When extended CP (=16.67
microsec) is used the total OFDM symbol time is (66.6 + 16.67) = 83.27
microseconds. Six OFDM symbols can then be placed in the 0.5-ms slot. Frames
are useful to send system information. Subframes facilitate resource allocation
and slots are useful for synchronization. Frequency hopping is possible at the
subframe and slot levels.
Type
2 LTE Frame Structure
Type 2 LTE Frame Structure
(shown for 5ms switch point periodicity).
The
subframes may be divided into standard subframes of special subframes. The
special subframes consist of three fields;
- DwPTS
- Downlink Pilot Time Slot
- GP
- Guard Period
- UpPTS
- Uplink Pilot Time Stot.
These
three fields are also used within TD-SCDMA and they have been carried over into
LTE TDD (TD-LTE) and thereby help the upgrade path. The fields are individually
configurable in terms of length, although the total length of all three
together must be 1ms.
Frame structure Type 2 is applicable to TDD is as
shown in the figure. Each radio frame of 10 ms in length consists of two
half-frames of 5 ms in length. Each half-frame consists of eight slots of the
length Ts=5 ms and three special fields DwPTS, GP, and UpPTS of 1 ms in length.
Different configurations, numbered zero to six, are
defined in the standard for the subframe number allocated for the uplink and
downlink transmission. Subframe 1 in all configurations and subframe 6 in
configurations 0, 1, 2 and 6 consist of DwPTS, GP and UpPTS. All other
subframes are defined as two slots.
Switch-point periodicities of 5 ms and 10 ms are
supported. The standard defines the table for the uplink and downlink
allocations for switch-point periodicity. In the case of a 5-ms switch-point
periodicity, UpPTS and subframes 2 and 7 are reserved for uplink transmission.
In the case of a 10-ms switch-point periodicity,
UpPTS and subframe 2 are reserved for uplink transmission and subframes 7 to 9
are reserved for downlink transmission.
Subframe 0 and 5 are always for the DL. The subframe
following the special SF is always for the UL. The DwPTS field carries
synchronization and user data as well as the downlink control channel for
transmitting scheduling and control information. The UpPTS field is used for
transmitting the PRACH and the Sounding Reference Signal (SRS).
LTE
TDD / TD-LTE subframe allocations
One
of the advantages of using LTE TDD is that it is possible to dynamically change
the up and downlink balance and characteristics to meet the load conditions. In
order that this can be achieved in an ordered fashion, a number of standard
configurations have been set within the LTE standards.
A
total of seven up / downlink configurations have been set, and these use either
5 ms or 10 ms switch periodicities. In the case of the 5ms switch point
periodicity, a special subframe exists in both half frames. In the case of the
10 ms periodicity, the special subframe exists in the first half frame only. It
can be seen from the table below that the subframes 0 and 5 as well as DwPTS
are always reserved for the downlink. It can also be seen that UpPTS and the
subframe immediately following the special subframe are always reserved for the
uplink transmission.
UPLINK-DOWNLINK CONFIGURATION
|
DOWNLINK TO UPLINK SWITCH PERIODICITY
|
SUBFRAME NUMBER
|
|||||||||
0
|
1
|
2
|
3
|
4
|
5
|
6
|
7
|
8
|
9
|
||
0
|
5 ms
|
D
|
S
|
U
|
U
|
U
|
D
|
S
|
U
|
U
|
U
|
1
|
5 ms
|
D
|
S
|
U
|
U
|
D
|
D
|
S
|
U
|
U
|
D
|
2
|
5 ms
|
D
|
S
|
U
|
D
|
D
|
D
|
S
|
U
|
D
|
D
|
3
|
10 ms
|
D
|
S
|
U
|
U
|
U
|
D
|
D
|
D
|
D
|
D
|
4
|
10 ms
|
D
|
S
|
U
|
U
|
D
|
D
|
D
|
D
|
D
|
D
|
5
|
10 ms
|
D
|
S
|
U
|
D
|
D
|
D
|
D
|
D
|
D
|
D
|
6
|
5 ms
|
D
|
S
|
U
|
U
|
U
|
D
|
S
|
U
|
U
|
D
|
Where:
D is a subframe for downlink transmission
S is a "special" subframe used for a guard time
U is a subframe for uplink transmission
D is a subframe for downlink transmission
S is a "special" subframe used for a guard time
U is a subframe for uplink transmission
Uplink
/ Downlink subframe configurations for LTE TDD (TD-LTE)
