3G WCDMA Interference Analysis Guide

Interference Analysis Guide

Key words

WCDMA, interference, main, diversity, RTWP, inter-modulation

Abstract

The document describes how to locate and solve interference issue in WCDMA network optimization.

Acronyms and abbreviations:

Acronyms and abbreviations Full Spelling

PIM Passive Interactive modulation

RTWP Received Total Wideband Power

BCCH Broadcasting Channel

FNE Fixed Network Element

AOA Angle of Arrival

1.1 Judging Types of Interferences

1.1.1 Interference Types

The interference includes internal interference and external interference.

The interference occurring on NodeB to the antenna-feeder system is internal interference.

The external interference includes in-band signal interference and out-band strong signal interference. The typical types are Personal Handy phone System (PHS) interference, repeater interference, and interference from handset interferer.

1.1.2 Criteria

The interference belongs to external interference if it meets the following judgment criteria:

The interference to main or diversity is relevant. Namely, in terms of time, the interference to main or diversity trends similarly, and the difference between them is within 5 dB.

The external interference affects multiple cells that are geographically bordering.

In terms of time feature of RTWP, the external interference is mutational, the interference occurs at a regular point and in a regular period, and lasts for a regular period (exceptions are microwave interference, improperly configured gain of repeaters, so the RTWP is not mutational)

The interference which is not external interference is internal interference, so it follows the internal interference processing procedures. Locating external interference takes more effort and time than locating internal interference. Therefore, if the interference is not confirmed to be internal interference, it must be rechecked. The inter-modulation interference which takes a high ratio in internal interference features typically as below:

The RTWP of main and diversity is usually irrelevant. If the RTWP is relevant, there must be special causes, such as the main and diversity are combined at some point.

The interference is related to traffic. The interference occurs less probably when traffic is lower.

The interference will last for a period, without mutational change, which is different from that of external interference.

In terms of time feature of RTWP, the RTWP changes irregularly.

The inter-modulation usually meets one or more of the previous five features. If the five features are all met, it must be inter-modulation.

For better understanding of the previous judgment criteria, the following examples provide direct phenomena of various interference from actual networks. Therefore no specific locating process is provided.

1.2 Equipment and Documents Needed In Interference

Test

1.2.1 Sturcture of Interference Test

The interference test uses the following structure of test equipment.

Figure 1-1Structure of interference test

1.2.2 Equipment and Documents

Table 1-1 lists the equipment and documents used in interference test.

Table 1-1Equipment and Documents

Equipment or document Type of connector Directional antenna N-type female connector,

For more info, see 4.1.3 Omnidirectional small antenna SMA-type female connector,

For more info, see 4.1.3

Directional Antenna

Equipment or document Type of connector Bandpass filter N-type female connector,

For more info, see 4.1.1 YBT250 spectrum analyzer N-type female connector 1/2 jumper x3 N-type male connector

1/2 jumper x2 N-type male connector/SMA male connector

50 Ohm Dummy Load x2 N-type male connector DIN-type male connector -> N-type

female connector x2

DIN-type female connector -> N-type female connector x2

N-type dual-female connector x2 Laptop (installed with NodeB LMT software)

GPS Compass Test car

FNE map of sites

Historic RTWP map of sites Distribution map of adjacent sites Camera

PHS handset (if to locate PHS interference)

Preparation for different connectors is a little complex and patient work. It’s better try each connection before go to test. Otherwise, you have to waste your time on spot.

2

Locating Interference

2.1 Locating Internal Interference

Locating internal interference includes initial location and on-site location.

2.1.1 Initial Location

The initial location proceeds as below:

Step 1 Check the configuration of diversity reception if you fail to observe the diversity signals. Figure 2-1 shows the RTWP variation when the diversity reception is not configured.

Figure 2-1RTWP variation when the diversity reception is not configured

Step 2 If the uplink RF channel has not been adjusted, check whether the configured gain (especially TMAs are used) of RF channel is correct. It is better to adjust uplink RF channel gain so that these problems will not bother locating interference. To check UL RF channel gain , the following steps has to be taken:

Install dummy load to the port to be checked;

Start NodeB LMT, Input MML command: SET TXSW: TXSW = OFF to switch off related PA in case of unexpected damage;

The RTWP normal value range is -105～-106dBm, Check whether measured RTWP value is in this range or not; If not, set attenuation of this channel to adjust RTWP to normal value. MML command: SET RXATTEN: ATTEN=***;

Uplink RF channel gain adjustment is not routine operation, which should be performed by RAN engineer when RAN engineer is available.

Step 3 If a DCS1800M network and a WCDMA network are combined, you must check the frequency configuration with operators. Meanwhile you must check whether the third order intermodulation (2f1-f2 and 2f2-f1) of the combined DCS1800M frequency is within the RX band (1920 MHz to 1980 MHz). If yes, negotiate with operators to change the improper frequency configuration.

If the interference remains after the previous operations, you must locate interference on site.

2.1.2 On-site Location

The on-site location proceeds as below:

Step 1 Start NodeB LMT and measure the real-time RTWP of the cell to be located. This allows you to observe real-time RTWP variation after using consequent locating methods.

Step 2 If a DCS network is combined to a WCDMA network, you must know the DCS carrier features (the carriers on a channel, the channel number, and the channel where BCCH is) and mark the BCCH channel.

Step 3 If a DCS network is combined to a WCDMA network, you need adjust BCCH to the channel where interference is located under assistance by the operator according to the result of interference. The reason is that if BCCH does not use the problematic channel (The GSM network might transmit signals in both channel, but the BCCH uses only one channel), it is very hard to locate DCS-traffic-related interference.

Step 4 Knock every RF connector gently on the channel (especially the connectors of jumper, load, and antenna) and check the RTWP variation. If RTWP changes, the connector is problematic. Tasks to improve project quality, such as fastening connectors and reconnections, must be perform under cooperation of the operators' engineers. Ensure to power off power amplifiers of corresponding cells before performing tasks to avoid radiation injury.

Step 5 When the connector are normal and interference is present, use YBT250, filter, and directional antenna to check at WCDMA antenna whether interference signals are received (for requirements on filter and directional antenna, see Appendix 4.1 In special situations, you must customize the filter according to the local WCDMA receiver band and other radio network transmission frequency band). If YBT cannot detect special interference, you need change the NodeB antenna and check whether the interference is caused inside the antenna. If the interference still exists after changing antennas, turn to judgment of interference types. Step 6 If interference signals are receives at the WCDMA antenna by using YBT250, filter, and

directional antenna, you can solve the problem by Locating External Interference. Step 7 If the interference cannot be located after repeated checks, solve it by Judging Types of

Interferences. Stop on-site location and restore the original configurations.

If successful in locating the interference, you can summarize the problem in the form of interference location cases based on "xx Interference Location Detailed Record". Send the cases to the Headquarter for filing.

If failing in locating the interference, you can send the "xx Interference Location Detailed Record" to technical support engineers in the Headquarter for help.

2.2 Locating External Interference

2.2.1 Preparations before On-site Location

It is hard to know when the external interference appears or disappears, so detailed preparations and analysis must be performed before on-site location. Otherwise, the on-site location will be less efficient.

1.

Needed Data

You need the following data:

The RTWP data for 7 (days, at least 3 days) x 24 (hours) of cells to be located The data is obtainable in "Collecting Data and Confirming Interference" section.

The MapInfo map of site distribution, the relative location of sites, and the distance between sites

You can use Nastar to obtain these information.

Antenna azimuth and height of cells

Photos for surveying sites

Whether the cell to be located is the host cell of a repeater

The distribution of 2G and 3G repeaters around the cell to be located

The distribution of PHS BTSs around the cell to be located

The antenna-feeder structure diagram of the cell to be located

2.

Needed Analysis and Initial Conclusion

Analysis: the long-time feature and short-time feature of RTWP data for the cell to be located in different periods Conclusion: the locating time (the periods when interference occurs intensively is obtainable according to RTWP time feature.

Analyze the following aspects:

Analyze the long-time feature and short-time feature of RTWP data for the cell to be located in different periods

Analyze the environment of the cell to be located with cell distribution diagram and surveying photo

Analyze the relativity of main and diversity of the cell to be located according to the antenna-feeder structure diagram

Use angle of arrival (AOA) to summarize the RTWP data of the cell to be located, the RTWP data of adjacent cells, antenna azimuth, and antenna height so that the location of the interference source can be estimated.

Locate the direction of the interference source by cell antennas of multiple NodeBs. Draw on a map, the crossing point of the direction of each antenna is the interference source.

Figure 2-2Locating interference source by using AOA

3.

Methods and Procedures for On-site Location

On-site location proceeds as below:

Step 1 Start NodeB LMT and monitor realtime RTWP of the cell to be located for the features and time when the external interference occurs.

Step 2 Check the environment of the antenna for metal blockings, antenna of other networks or systems, the antenna distribution of other operators. Check the potential adjacent blockings to signals.

Step 3 Measure the interference strength, direction, and frequency spectrum by using YBT250, filter, and antenna.

Step 4 Find the rough location of the interference source. For more interference-locating methods and experience, see chapter Method and experience in external interference location. Step 5 Fix the potential interference source according to the previous analysis.

Step 6 Verify the relationship between the interference and the state variation of the potential interference source (such as on, off, starting, and stopping)

For the equipment that is controlled by the operator, such as repeaters, you can verify the relations between the equipment and the interference by powering on or off the equipment in a proper time. For the uncontrollable equipment, you need to wait to observe the interference. Step 7 Record the previous locating steps in the form of "xx Interference Location Detailed Record".

If successful in locating the interference, you can summarize the problem in the form of interference location cases based on "xx Interference Location Detailed Record". Send the cases to the Headquarter for filing.

If failing in locating the interference, you can send the "xx Interference Location Detailed Record" to technical support engineers in the Headquarter for help.

3

Case study

3.1 Cases of Internal Interference

3.1.1 Multi-frequency Intermodulation Due to Load

In an indoor distributed system, the 3G signals, 2G signals of the operator S, and 2G signals of the operator P are combined. The operator P uses the absolute radio frequency channel number (ARFCN) 747. The operator S uses the ARFCN 850 and hopping frequency ARFCN 815.

Figure 3-1 shows the variation of RTWP.

Figure 3-1Variation of RTWP due to load

The interference in the cell is caused by a load with loose connection. Once the load is touched, the RTWP changes sharply.

The RTWP changes as below:

The main and diversity are irrelevant

The RTWP fluctuates sharply

The interference lasts for a period

3.1.2 Multi-frequency Intermodulation Due to Improper

Connection of Multiple RF

The multiple RF connection involves duplexer, feeder, and jumper connector.

The site is constructed with indoor distribution system shared by multiple operators. The antenna-feeder structure is complex. Wherein, multiple hybrid couplers, feeders, and jumpers are improperly connected, so the RTWP is as shown in Figure 3-2.

Figure 3-2Variation of RTWP due to improper connection of multiple RF

The RTWP changes as below:

The RTWP fluctuates sharply

The interference lasts for a period

The RTWP changes irregularly in terms of time

3.1.3 Single Frequency Intermodulation Due to Improper

Connection of Feeder and Jumper

The 3G signals and 2G signals are combined. The 2G network uses only one channel number. Intermodulation occurs due to improper connection of feeder and jumper.

Figure 3-3Antenna-feeder structure

Figure 3-4 shows the variation of RTWP due to improper connection of feeder and jumper.

Figure 3-4Variation of RTWP

The RTWP changes as below:

The main and diversity are irrelevant

The RTWP fluctuates sharply

The interference lasts for a period

The RTWP changes irregularly in terms of time

3.1.4 Multi-frequency Intermodulation Due to Interaction of 2G

and 3G signals

This is an indoor site, with 2G and 3G signals combined. It is an indoor distributed system shared with other operators.

Figure 3-5Variation of RTWP due to interaction of 2G and 3G signals

In Figure 3-5, the main interference (in red) is caused by intermodulation of DCS signals and 3G signals at a connector.

The diversity is not connected to antenna. The external signals near cabinet interferes diversity.

The RTWP changes as below:

The main and diversity are irrelevant

The RTWP fluctuates sharply

The interference lasts for a period

The RTWP changes irregularly in terms of time

3.2 Cases of External Interference

3.2.1 Sites Around Repeaters of Self-excitation Interference

Figure 3-6Site distribution around the site 501800

In the network as shown in Figure 3-6, a 3G repeater close to the NodeB 501800 transmits a self-excitation signal every hour approximately. Therefore the uplink in multiple cells is interfered. The uplink interference varies according to the direction and the distance between the cell and the repeater. However, it is clear that the uplink interference occurs every hour approximately.

Figure 3-8Variation of RTWP in adjacent cells (2)

Figure 3-9Variation of RTWP in adjacent cells (3)

Figure 3-11Variation of RTWP in adjacent cells (5)

Figure 3-12Variation of RTWP in adjacent cells (6)

The site 501800 is an indoor site with a single antenna.

The RTWP changes as below:

The main and diversity are relevant

The interference influences multiple cells that are close to each other

The interference is mutational

The interference changes with a regular internal

3.2.2 Uplink Interference to Host Cell Due to Repeater

Self-excitation

The NodeB 45680 uses a 3G repeater. The host cell of the repeater is the first cell 54291 of the NodeB 45680. The occurrence time of self-excitation of the repeater is irregular.

Figure 3-13Variation of RTWP

The RTWP changes as below:

The main and diversity are relevant

The interference is mutational

3.2.3 Uplink Interference to Host Cell Due to Improperly

Configured Gain of Repeater and Self-excitement

The gain of the repeater is 90 dB. Figure 3-14 shows the RTWP variation of cell 45680.

Figure 3-14RTWP variation of cell 45680

After adjustment of the repeater gain to 70 dB, the RTWP becomes normal.

The RTWP variations feature the same as that of improperly configured gain of repeater. Namely, the interference is strong and stable.

3.2.4 Uplink Interference to 3G Antenna Due to Close Radiation

from 2G Repeater Antenna

shown in Figure 3-15, the 3G antenna is a diversity antenna and the main antenna is far from 2G antenna.

Figure 3-15Antenna location

Figure 3-16RTWP variation

The RTWP changes as below:

The main and diversity are relevant

The interference is mutational

3.2.5 RTWP Variation Due to Passing Trains

The NodeB is close to the railway with intensive trains passing by. Figure 3-17 shows the site location near the railway.

Figure 3-17Site location

Figure 3-18RTWP variation of a NodeB near railway

3.2.6 Uplink Interference Due to State Switch of Indoor

Air-conditioner Controller

Figure 3-19RTWP variation due to indoor air-conditioner

3.2.7 Uplink Interference Due to Power On or Off of Outdoor

Air-conditioner of Other Operator

Figure 3-20 shows the RTWP variation due to power on or off of outdoor air-conditioner of other operator.

Figure 3-20RTWP variation due to power on or off of outdoor air-conditioner of other operator

3.2.8 Uplink Interference Due to Power On or Off of Indoor

Emergency Lights

Figure 3-21RTWP variation due to power on or off of indoor emergency lights

3.2.9 Uplink Interference with Period of 200 Seconds

This uplink interference is probably due to air-conditioner compressor, but this cannot be confirmed due to property restriction.

Figure 3-22 shows the long-time RTWP variation.

Figure 3-22Long-time RTWP variation

Figure 3-23Short-time RTWP variation

The RTWP changes as below:

The main and diversity are relevant

The interference is mutational

The interference changes with a regular internal

3.2.10 Interference Caused by the Spectrum Analyzer YBT250 at

1924.3 MHz

Figure 3-24 shows the interference caused by the spectrum analyzer YBT250 at 1924.3 MHz when the directional antenna approaches the YBT250.

Figure 3-24Frequency spectrum when the directional antenna approaches the YBT250

When locating interference, pay attention to the feature of YBT250.

3.2.11 Uplink Interference Due to Transmission Line

Figure 3-25Uplink interference due to transmission line (1)

Figure 3-26Uplink interference due to transmission line (2)

3.2.12 Interference Like Self-excitation

Figure 3-27Long-time RTWP variation of the interference like self-excitation

Figure 3-28 shows the short-time RTWP variation of the interference like self-excitation.

Figure 3-28Short-time RTWP variation of the interference like self-excitation

Figure 3-29 shows the frequency spectrum feature.

Figure 3-29Frequency spectrum feature

The scanned frequency ranges from 1914 MHz to 1951 MHz

The amplitude of different frequencies is different

The frequency jumps after a scanning period The RTWP changes as below:

The main and diversity are relevant

4

Appendix

4.1 Key Device Parameters

4.1.1 Filter

The bandwidth of the bandpass filters used for uplink/downlink electromagnetic interference tests is 60 MHz. For the specifications, see Table 4-1. The bandpass filter allows the signals within the useful frequency band to pass and suppresses interference signals beyond the useful frequency band. Figure 4-1 shows a bandpass filter. Generally, the two ends of the bandpass filter can serve as an input or output end.

Figure 4-1Bandpass filter

Table 4-1Specifications for uplink and downlink bandpass filters Operating Frequency (MHz) 1920 to 1980 2110 to 2170 0.7 dB at 1920 MHz 0.9 dB at 2110 MHz 0.4 dB at 1950 MHz 0.3 dB at 2140 MHz Insertion Loss 0.7 dB at 1980 MHz 0.7 dB at 2170 MHz –3-dB Bandwidth (MHz) 1912–1987 2106–2177 Out-of-band suppression ≥ 70 dB (1900–1999 MHz) ≥ 70 dB (2090–2192 MHz)

Operating Frequency (MHz) 1920 to 1980 2110 to 2170 VSWR < 1.15 < 1.15 Group Delay (ns) 30–50 30–50

4.1.2 Low-Noise Amplifier

Although a low-noise amplifier (LNA) is built in the YBT250, the noise figure is so high that it is difficult for the receiver sensitivity to meet the requirement. Therefore, an external LNA is required to improve the receiver sensitivity of the tester. For a cascade network, with a high-gain amplifier installed at the front end of the system, the noise figure of the system depends on the noise figure of the first LNA. Therefore, a ZRL-2400LN low-noise amplifier of Mini-Circuits is selected. The gain is 25 dB and the noise figure is 1.2 dB. However, an extra power supply is required for the LNA.

Table 4-2Specifications for the LNA

4.1.3 Antenna

An omni-directional antenna can be used for electromagnetic interference measurement, but it is not favorable for locating interference sources. It is recommended that a directional antenna be used to locate interference sources. The higher the antenna directivity is, the higher the gain and the search capability are. Common directional antennas include plate antennas, Yagi antennas, and log periodic antennas. For convenience, only a directional antenna is used for tests in different directions. A Yagi antenna is used for narrowband and high-gain short-wave communication. A Yagi antenna is simple, light but solid, and convenient to feed, however, the frequency band of such an antenna is narrow and the resistance to interference is low. A log periodic antenna is a broadband antenna or a frequency-independent antenna. Compared with other high-gain antennas, a log periodic antenna has a higher directivity and a larger attenuation to signals in unexpected directions. Therefore, a log periodic antenna is preferred in interference tests. A log periodic antenna (see Figure 4-2) made by Shenglu Antenna Co., Ltd. is used. For the major technical specifications, see Table 4-3.

Figure 4-2Log periodic antenna SL14088A

Table 4-3Major technical specifications of a log periodic antenna Major Technical Specifications

Model SL14088A Frequency Range 806 MHz to 960 MHz, 1710 MHz to 2500 MHz VSWR < 1.5 Input Impedance 50 Ω Gain 11 dBi Front-to-Back Ratio 12 dB Horizontal Lobe Width 50°±10° Vertical Lobe Width 40°

Polarization Mode Vertical or horizontal

Maximum Power 50 W

Grounding Mode DC grounding Input Interface N female connector

If no log periodic antenna is available, a Yagi antenna can be used. Table 4-4 lists the major technical specifications of a Yagi antenna manufactured by Shenglu Antenna Co., Ltd.

Table 4-4Major technical specifications of a Yagi antenna Major Technical Specifications

Model TDJ-1800/2000B14G13

Frequency Range 1710 MHz to 2150 MHz

VSWR <1.5

Input Impedance 50 Ω

Major Technical Specifications Front-to-Back Ratio 18 dB

Lobe Width 41°

Polarization Mode Vertical or horizontal

Maximum Power 150 W

Grounding Mode DC grounding Input Interface N female connector

An omni-directional vehicle mounted antenna (see Figure 4-3) manufactured by Shenglu Antenna Co., Ltd. is used. Table 4-5 lists the major technical specifications.

Figure 4-3Omni-directional vehicle mounted antenna SL15209A

Table 4-5Major technical specifications of an omni-directional vehicle mounted antenna Major Technical specifications

Model SL15209A

Frequency Range 880 MHz to 965 MHz/1710 MHz to 2170 MHz

VSWR <2.0

Input Impedance 50 Ω

Gain ≥ 3 dBi

Polarization Mode Vertical

Maximum Power 50 W

4.2 Method and experience in external interference

location

4.2.1 Middle location

Determine the possible location of interference according to RTWP statistics and environment. Perform bidirectional test around the interference source to approach the source. This is called the middle location.

Figure 4-4Schematic drawing of middle location

4.2.2 Two-point location

The precaution for this method is that you must know the approximate interference direction. In the direction, measure the signals to compare the signal strength in two selected spots. Locate the interference by calculating the variation of interference strength.

To use the variation of signal strength for interference location, you must know the direction and approximate location of interference. Then move a omnidirectional antenna to the interference and judge the location relationship between the omnidirectional antenna and the interference. Finally fix the specific location of interference near the interference source by using the directional antenna.

Figure 4-5Schematic drawing of two-point location

4.2.3 Method of Locating the Field Strength Change

Step 2 Move an omni-directional antenna towards the interference source and determine the position relationship between the speed of signal change and the interference source.

Step 3 Use a directional antenna nearby the interference source to find out its specific position.

4.2.4 Case Study of Locating an Interference Source

In an urban area, the long-distance direction finding is usually accurate. However, after you approach the interference source, it is difficult to determine its position on the ground owing to strong signal reflection and refraction in a short distance.

Tests are usually conducted at crossroads where high buildings and large advertisement signs stand and signal reflection and shielding occur. Therefore, when you move towards the direction finding direction, you should pay close attention to the change in the field strength. If the field strength decreases, the direction finding direction is very likely incorrect. Owing to the reflection and refraction caused by some high buildings, the field strength within a small range far away from the interference source increases. This may lead you to the wrong direction and wander there for a long time. In such a case, it is important that you identify the problem and find another direction finding point to locate the interference source.

A great error exists in direction finding near railway tracks or high-voltage lines. You should avoid performing direction finding near such places.

You can adopt the cross location method and field-approaching method, but avoid climbing up buildings. The probability of locating the interference source is high on a high building; however, it is not recommended that you climb up the building to locate the direction. If you are not familiar with the terrain, you may make mistakes in identifying the point. It is also difficult to contact the occupants of the building before climbing the building. It is advisable to first determine the rough direction of the interference source at the selected place, and then approach the interference source according to the field strength change in a drive test. Owing to the effect of fast fading during movement of the vehicle, the field strength is not steady at times. You should pay attention to the average and maximum field strengths when locating an interference source. At crossroads, especially an overpass (the relative relief is high), you should slow down to reduce the effect of fast fading so that you can accurately locate the direction of interference source.

With the cooperation of the YBT250, the log periodic antenna can achieve good direction finding results in a far field or near field. As you can read the signal level during a drive test, you can determine whether you are approaching or moving away from a signal source. The effect is considerably satisfactory. The YBT250 can simultaneously display the signal average and the signal level. During direction finding, you do not need to use it to memorize the levels in different direction, but directly use the level value and the average value to quickly locate the direction. The combination of the YBT2500 with a log periodic antenna does not apply to an intermittent interference source. When you approach the interference source, especially signals in a building, it is satisfactory to use the audio method of the YBT250. You can judge the specific position of a signal source according to the sharpness or flatness of the sound generated by the YBT250.

The Okumura's empirical formula for propagation loss is as follows:

Lm = 69.55 + 26.16lOg(f) – 13.82log(hb) – a(hm) + [44.9 – 6.55lOg(hb)]lOg(d)

In this formula, it can be seen that the receiving level of signals during interference source finding is related to only one variable—distance. The signal level changes significantly near the interference source. Therefore, when the signal level is low, determine the direction of the interference source, drive the vehicle fast and compare the field strengths. When the signal level is high, approach the interference source in the given direction until the level is above –60 dBm. Then, monitor the field strength as you walk in the area until the field strength is –50 dBm. Then, climb up the building to locate the source of interference.

It is unnecessary to use an antenna operating in the test band. As direction finding only involves the comparison of signal strength, it is sufficient if the antenna used can receive signals. Thus, the time for replacing antennas can be saved. You need to ensure that the difference between the frequency band in which the antenna operates and the frequency of the signals to be searched should not be too great.

When searching for an interference source, you should comprehensively consider, analyze, and determine the direction indication, strength, and surrounding environment. However, a rapid change in the field strength is the most important factor when searching for the interference source in a complex environment. If the field strength change is insignificant even near the interference source, the monitoring device may be in the saturation state. In this case, you can increase the attenuation at the input end of the monitoring device or remove a normal antenna