Because of its portability, the non-cable seismograph has become the future development trend of geophysical instruments. A new wireless data transmission device of 433 M module was proposed; a wireless network was built using the EL1663B_PA module of the SI4463 core, and through the SPI interface to modify the internal parameters. Data transmission used dual antenna mode, the main station as the center of the wireless network coverage up to 550 m or more. The wireless time synchronization system was designed to realize the wireless connection communication between the shallow seismograph and the sensor of each observation point. This program aimed to eliminate the necessary connecting cable and batteries between the conventional shallow seismograph and the detector, greatly reducing the weight of the equipment, and making the shallow seismograph truly low cost, lightweight, flexible and easy to operate and so on.
In recent years, China has made a large number of investments in the high-speed rail, highways, airports and other infrastructure areas, which makes the shallow detection arouse more and more attention. The shallow seismograph transmission method is divided into two kinds, the cable and the non-cable, and the widely used is the cable acquisition technology [
The non-cable seismograph is mainly transmitted through wireless communication technology [
| Name | Transmission Speed/Mbps | Communication Distance/m Distance | Frequency Range/ GHz | Safety | International Standard | Power Dissipation/ mA |
|---|---|---|---|---|---|---|
| 433 M module | 1 | 1000 | 0.433 | Low | Not Formulated | <500 |
| Wi-Fi | 54 | 100 | 2.4 | Low | IEEE.802.11b/ IEEE.802.11g | 10~50 |
| Bluetooth | 1 | 15 | 2.4 | High | IEEE.802.15.1x | 20 |
| ZigBee | 0.25 | 20 | 2.4 | Medium | IEEE802.15.4 | 5 |
| UWB | 53~480 | 10 | 3.1~10.6 | High | Not Formulated | 10~50 |
| RFID | 0.001 | 1 | 0.868~0.915 | Low | Not United | 10 |
The module for wireless transmission system used the SI4463 [
| State/Mode | Response Time to | Current in State/mA | |
|---|---|---|---|
| TX/µs | RX/µs | ||
| Shutdown State | 15000 | 15000 | 3 × 10−5 |
| Standby State | 440 | 440 | 5 × 10−5 |
| Sleep State | 440 | 440 | 9 × 10−4 |
| SPI Active State | 340 | 340 | 1.35 |
| Ready State | 126 | 122 | 1.8 |
| TX Tune State | 58 | - | 8 |
| RX Tune State | - | 74 | 7.2 |
| TX State | - | 138 | 18 |
| RX State | 130 | 75 | 10 or 13 |
According to the structure of the network mainstation and sub-station of non-cable seismometer and data using dual antenna combination transmission characteristics, the circuit of the wireless transmission module is designed by SI4463, as shown in
The transmitting power required for data transfer is related to factors such as antenna height, communication distance and bit rate. The effective transmission distance of the network can be expressed by the following equation.
r = ( 30 × E I R P E RXsens ) 2 n 2 n − 2 2 E RXsens = 1000 480 π 2 ( c / f ) 2 G RX p RXsens (1)
where EIRP is the equivalent transmit power; n is the equivalent propagation constant of the medium, рRXsens is the receiver sensitivity, GRX is the receiving antenna gain; c is the speed of light; f is the electromagnetic wave frequency. From this equation it is known that choosing the lower carrier frequency can get a larger transmission distance in the case of the same transmit power. So we gave up the ZigBee network [
According to the workflow of shallow seismograph, the amount of data of the downlink of the wireless transmission (i.e. the host to the sub-station) is small. A large number of transmission data mainly occurred when the data acquisition was completed and the seismic wave data was uploaded. The sensitivity of SI4463 receiver and the bit rate of data transmission are related. In the bit error rate of less than 1% of the conditions, the SI4463 receiver sensitivity and the bit rate of the relationship between the curves are shown in
The host issues a command, due to the small amount of data there is no delay problem. Using lower 10 kbps bit rate data transmission to improve the reliability of command transmission. The command format is shown in
| Command Identifier/byte | Command Code/byte | Target Node Number/byte | Command Length/byte | Command Parameter/byte | Check Code/byte |
|---|---|---|---|---|---|
| (0 × A2) 1 | 1 | 1 | 1 | n | 2 |
When data acquisition is completed, data upload is a task of consuming network resources, so increasing the speed of data upload is a key issue in this design. SI4463 supports the highest baud rate 1 Mbps data transmission; the relationship between the receiver sensitivity and the bit rate is taken into account. In the establishment of the wireless network, through the test of sub-station uplink signal strength, communication quality and bit-error rate selection of transfer process, we divided the bit rate into three, 100 kbps, 50 kbps, and 10 kbps, respectively.
SI4463 TX FIFO is 64 bytes, the packet length according to this design. Data transfer is made after the main station issues a data transfer request. Therefore, the structure of the packet is designed as shown in
In the transmission of commands and responses, in order to ensure the high reliability of the transmission, there is an ACK response transmission. In the packet transmission, in order to improve the transmission rate, the non-ACK response transmission was used to avoid the SI4463 to receive and send the conversion time to spend. Using the non-ACK response transmission can greatly improve the data transmission rate. The test analysis shows that a 64-byte packet with non-ACK response transmission time is about 7.6 ms, while the ACK response transmission time is about 10.2 ms in the case of 100 kbps bit rate. Therefore, a non-ACK response transmission was used to improve the data transmission rate, such a 2048 sample of the test data transmission time of about 1 second.
| Response Identifier/ byte | Packet Identifier/ byte | Source Node Number/ byte | Packet Length/ byte | Sampling Point Number/byte | Sampled Data/ byte | Check Code/ byte |
|---|---|---|---|---|---|---|
| (0 × 55) 1 | 1 | 1 | 1 | 2 | 3n | 2 |
However, in data transmissions, packet loss events will inevitably occur. The main station will discover the sample point number of the lost packet when the data connection is made and instruct the sub-station to retransmit the data.
| Bit Rate Selection/byte | Sampling Point Number/byte | Number of Packets/byte | Sampling Point Number/byte | Number of Packets/byte | … |
|---|---|---|---|---|---|
| 1 | 2 | 1 | 2 | 1 | … |
When the seismic wave is excited, the data acquisition command is sent by the source excitation sub-station. However, from the excitation to the acquisition sub-station to resolve the command about 2 ms delay, the delay is uncertain. If there is communication channel interference, the delay may be longer, so the time synchronization must be performed. In this paper, a wireless acquisition system with a crystal oscillator of 8 MHz was used, and the time synchronization error did not exceed 25 μs in the one acquisition process. It can meet the vast majority cases of data acquisition synchronization requirements. If you need a higher time synchronization accuracy, a higher frequency of the crystal oscillator can be used.
As shown in
After the time synchronization was completed, the trigger sub-station triggers an artificial seismic wave and sends a data acquisition command that contains the system timestamp of the seismic wave excitation time. After the acquisition sub-station received the command, according to the timestamp in the packet and the current system clock, the storage address of the acquisition data of the seismic wave excitation time was calculated in the buffer. With this address as the starting point, the subsequent data is valid seismic wave data.
To verify the effectiveness of this program, an effective communication distance test was carried out in front of the square of main building of the Yangtze University, as shown in
In order to meet the different operating conditions, this program was equipped with high-gain of glue rod antenna and ultra-high gain of the elevated antenna, as shown in
The test program of effective communication distance of wireless network refers to the seismograph mainframe of wireless data module (base station) and the wireless data acquisition transmission port (sub-station) composed of SI4463 dual antenna transceiver system; When the base station is stationary, the sub-station and cell-phone range locator are moving along the line; The effective communication distances of 10 Kb/s, 50 Kb/s and 100 Kb/s transmission rates were measured in different combinations of glue rod and elevated antenna. After repeated tests, we obtained the transmission distance under different test conditions, as shown in
| Base Station | Sub Station | Transmission Rate (Kb∙s−1) | Effective Transmission Distance/m | Remarks |
|---|---|---|---|---|
| Glue Rod Antenna | Glue Rod Antenna | 10 | 150 | Barrier free, signal value greater than 70 dBm |
| Glue Rod Antenna | Glue Rod Antenna | 50 | 120 | Barrier free, signal value greater than 70 dBm |
| Glue Rod Antenna | Glue Rod Antenna | 100 | 100 | Barrier free, signal value greater than 70 dBm |
| Elevated Antenna | Glue Rod Antenna | 10 | 240 | Dwarf tree barrier, signal value greater than 70 dBm |
| Elevated Antenna | Glue Rod Antenna | 50 | 180 | Barrier free, signal value greater than 70 dBm |
| Elevated Antenna | Glue Rod Antenna | 100 | 130 | Barrier free, signal value greater than 70 dBm |
| Elevated Antenna | Elevated Antenna | 10 | 320 | Dwarf tree barrier, signal value greater than 70 dBm |
| Elevated Antenna | Elevated Antenna | 50 | 250 | Dwarf tree barrier, signal value greater than 70 dBm |
| Elevated Antenna | Elevated Antenna | 100 | 200 | Barrier free, signal value greater than 70 dBm |
According to test results of effective communication distance, the base station is placed in the center of the survey line, and the effective coverage length of the wireless network can be doubled on the basis of the
The rapid development of the seismic exploration puts forward higher requirements for the seismograph technology and equipment. In view of the increasingly complex construction environment and the increasing construction area and engineering quantity, the development of non-cable seismographs has been paid more and more attention by the industry. The reliability of data transmission system of wireless seismograph is a technology problem; a shallow seismograph wireless transmission system based on 433 M module is designed in this paper. It implements the command and data wireless transmission, reducing the weight of the instrument, saving time of line layout, and greatly improving the work efficiency. Verified by the field test, the effective communication distance of the wireless network can reach more than 550 m, fully meeting the needs of shallow seismic exploration. This program can quickly recover the field data, and provide strong support for real-time construction of engineering geophysical prospecting.
This work was supported by the National Natural Science Foundation of China (grant number 41774116).
The authors declare no conflicts of interest regarding the publication of this paper.
Liu, L., Zhang, C.G., Li, T.Q., Liu, Y., Jin, Y. and Zhou, C. (2019) Design of Wireless Transmission System for Shallow Seismograph Based on 433 M Module. Open Journal of Yangtze Gas and Oil, 4, 89-99. https://doi.org/10.4236/ojogas.2019.42007