WMAN_UL_802_16e_RX_Sensitivity

This section provides parameter information for Required Parameters, Basic Parameters, Signal Parameters, and parameters for the various measurements.

Setting Parameters

More control of the test bench can be achieved by setting parameters in the Basic Parameters , Signal Parameters , and measurement categories for the activated measurements.

Note For required parameter information, see Set the Required Parameters.

Basic Parameters

1. SourceR is the RF output source resistance.
2. SourceTemp is the RF output source resistance temperature (oC) and sets noise density in the RF output signal to (k(SourceTemp+273.15)) Watts/Hz, where k is Boltzmann's constant.
3. MeasR defines the load resistance for the RF DUT output Meas signal into the test bench. This resistance loads the RF DUT output; it is also the reference resistance for Meas signal power measurements.
4. TestBenchSeed is an integer used to seed the random number generator used with the test bench. This value is used by all test bench random number generators, except those RF DUT components that use their own specific seed parameter. TestBenchSeed initializes the random number generation. The same seed value produces the same random results, thereby giving you predictable simulation results. To generate repeatable random output from simulation to simulation, use any positive seed value. If you want the output to be truly random, enter the seed value of 0.

Signal Parameters

1. GainImbalance, PhaseImbalance are used to add certain impairments to the ideal output RF signal. Impairments are added in the order described here.
   The unimpaired RF I and Q envelope voltages have gain and phase imbalance applied. The RF is given by:
   
   where A is a scaling factor that depends on the SourcePower and SourceR parameters specified by the user, V I( t ) is the in-phase RF envelope, V Q( t ) is the quadrature phase RF envelope, g is the gain imbalance
   
   and, φ (in degrees) is the phase imbalance.
2. Bandwidth determines the nominal channel bandwidth.
3. OversamplingOption indicates the oversampling ratio of transmission signal. There are six oversampling ratios (1, 2, 4, 8, 16, 32) to support in this source.
4. FFTSize specifies the size of FFT. Sizes 2048, 1024 and 512 are supported.
5. CyclicPrefix specifies the ratio of cyclic prefix time to "useful" time, whose range is from 0 to 1.
6. FrameMode determines what will actually be included in the generated waveform. FDD Mode means the entire frame is used for the uplink and the uplink starts at the beginning of the frame. TDD Mode means only the uplink is included in the generated waveform and it starts at some delay from the frame start time based on the Downlink Ratio setting.
7. DL_Ratio set the percentage (1 to 99) of the frame time to be used for the downlink and also set the start time for the uplink. The parameter is only active when the FrameMode is TDD.
8. FrameDuration determines the frame durations (ms) of the generated waveform.There are eight frame durations (2ms, 2.5ms, 4ms, 5ms, 8ms, 10ms, 12.5ms, 20ms) to be selected as allowed by the specification.
9. PreambleIndex specifies the preamble index number (0 to 113). The preamble index value determines the ID Cell values (0 to 31) and segment index (0 to 2) according to the standard.
10. UL_PermBase specifies the permutation base that will be used in this uplink zone. Accepted values are 0 to 69.
11. ZoneType specifies the zone type which can be set to PUSC or OPUSC.
12. ZoneNumOfSym specifies the number of symbols in the zone. The value must be a multiple of three because the uplink zone is divided into slots of 3 symbols x 1 subchannel (section 8.4.3.1 in 802.16e-2005). The maximum number of symbols available depends on the Bandwidth , FrameDuration , DL_Ratio , FFTSize , and CyclicPrefix .
13. NumberOfBurst specifies the number of active uplink bursts.
14. BurstWithFEC specifies the uplink burst FEC.
15. BurstSymOffset positions each burst on the horizontal axis (x), if necessary, to avoid any burst overlap. The parameter is an array element.
16. BurstSubchOffset positions each burst on the vertical axis (y), if necessary, to avoid any burst overlap. The parameter is an array element.
17. BurstAssignedSlot specifies the total available slots in each burst. The parameter is an array element.
18. DataLength specifies MAC PDU payload byte length for each burst.
19. CodingType specifies the coding type for each burst. Each coding type can be selected from 0 to 1, whose meaning is shown in The meaning of coding type.
    

    The meaning of coding type

    Coding type	meaning
    0	Convolutional coding (CC)
    1	Convolutional turbo coding (CTC)

20. Rate_ID specifies the rate ID for each burst. Rate_ID, along with CodingType, determines the modulation and coding rate, shown in The relation of Coding type and Rate ID.
    

    The relation of Coding type and Rate ID

    Coding type	Rate ID	Modulation/Coding rate
    0 (CC)	0	QPSK CC1/2
    0 (CC)	1	QPSK CC3/4
    0 (CC)	2	16-QAM CC1/2
    0 (CC)	3	16-QAM CC3/4
    0 (CC)	4	64-QAM CC1/2
    0 (CC)	5	64-QAM CC2/3
    0 (CC)	6	64-QAM CC3/4
    1 (CTC)	0	QPSK CTC1/2
    1 (CTC)	1	QPSK CTC3/4
    1 (CTC)	2	16-QAM CTC1/2
    1 (CTC)	3	16-QAM CTC3/4
    1 (CTC)	4	64-QAM CTC1/2
    1 (CTC)	5	64-QAM CTC2/3
    1 (CTC)	6	64-QAM CTC3/4
    1 (CTC)	7	64-QAM CTC5/6

21. RepetitionCoding specifies the repetition coding for each burst. Each repetition coding can be selected from 0 to 3, whose meaning is shown in The meaning of repetition coding.

    Repetition coding	meaning
    0	No repetition coding on the burst
    1	Repetition coding of 2 used on the burst
    2	Repetition coding of 4 used on the burst
    3	Repetition coding of 6 used on the burst

22. BurstPowerOffset determines the power offset of each burst in dB. The parameter is an array element.
23. DecoderType specifiers the Viterbi decoder type chosen from CSI, Soft and Hard.
24. StopFrame specifiers the stop burst used for BER and FER calculation.

Measurement Parameters

1. DisplayPages provides Data Display page information for this measurement. It cannot be changed by the user.

Simulation Measurement Displays

After running the simulation, results are displayed in the Data Display pages for each measurement activated.

Note Measurement results from a wireless test bench have associated names that can be used in Data Display Expressions. For more information, refer to Measurement Results for Expressions.

Sensitivity Measurement

The sensitivity measurement shows BER and PER results. The BER measured after FEC shall be less than 10^(-6) at the power levels RSS defined in equation (149b) of section 8.4.13.1 of Reference [2] (assuming 5dB implementation margin and 8dB Noise Figure). Simulation results for "Rate_ID = 5" and SourcePower of -75 dBm are displayed in Simulation Results for "Rate_ID = 5" and -75 dBm SourcePower.

Simulation Results for "Rate_ID = 5" and -75 dBm SourcePower

Test Bench Variables for Data Displays

Variables listed in Test Bench Variables for Data Displays are used to set up this test bench and data displays.

Test Bench Variables for Data Displays

Data Display Parameter	Equation with Test Bench Parameters
RF_FSource	FSource
RF_Power_dBm	10*log10(SourcePower)+30
RF_R	SourceR
TimeStep	1/SamplingFrequency/(2^OversamplintOption)
SamplingFrequency	Bandwidth*n (n is sampling factor)
Bandwidth	Bandwidth
RateID	Rate_ID
CyclicPrefix	CyclicPrefix
Data_Length	DataLength
Frame_Duration	FrameDuration
Frame_Mode	FrameMode
DL_Ratio	DL_Ratio
Meas_FMeasurement	FMeasurement
Meas_R	MeasR

Baseline Performance

• Test Computer Configuration
  • Pentium IV 2.26 GHz, 1024 MB RAM, Windows 2000
• Conditions
  • Measurements made with default test bench settings.
  • RF DUT is an RF system behavior component.
  • Resultant WTB_TimeStep = 44.643 nsec; Frame_Duration = 5 msec
• Simulation time and memory requirements:

  WMAN_UL_802_16e_RX_Sensitivity_test Measurement	Frames Measured	Simulation Time (hour)	ADS Processes (MB)
  RX Sensitivity	100	2	300

Expected ADS Performance

Expected ADS performance is the combined performance of the baseline test bench and the RF DUT Circuit Envelope simulation with the same signal and number of time points. For example, if the RF DUT performance with Circuit Envelope simulation alone takes 2 hours and consumes 200 MB of memory (excluding the memory consumed by the core ADS product), then add these numbers to the Baseline Performance numbers to determine the expected ADS performance. This is valid only if the full memory consumed is from RAM. If RAM is less, larger simulation times may result due to increased disk access time for swap memory usage.

References

1. IEEE Std 802.16-2004, Part 16: Air Interface for Fixed Broadband Wireless Access Systems, Section 8.4 WirelessMAN-OFDMA PHY, October 1, 2004.
2. IEEE Std 802.16e-2005, Amendment 2: for Physical and Medium Access Control Layers for Combined Fixed and Mobile Operation in Licensed Bands and Corrigendum 1, - Part 16: Air Interface for Fixed Broadband Wireless Access Systems, Section 8.4 WirelessMAN -OFDMA PHY, February 2006.

Setting up a Wireless Test Bench Analysis in the Wireless Test Bench Simulation documentation explains how to use test bench windows and dialogs to perform analysis tasks.

Setting Circuit Envelope Analysis Parameters in the Wireless Test Bench Simulation documentation explains how to set up circuit envelope analysis parameters such as convergence criteria, solver selection, and initial guess.

Setting Automatic Behavioral Modeling Parameters in the Wireless Test Bench Simulation documentation to learn how to improve simulation speed.