S15: Wireless Mesh Network

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• How well is Software & Hardware Design described?
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    Schematic Quality

  • Quality of technical challenges and solutions adopted.

Project Title

Wireless Mesh Network

Abstract

A mesh network topology is a design in which each node in the network is connected to at least two other nodes in the network. Communication between two nodes is established without a internet connection. Each node in the network can talk to every other node in the network by exchanging a payload data. An important feature of mesh network is that there is no single point of failure(SPoF), i.e. data is transmitted via an alternative route even if a node in the network fails. In this project we are implementing a wireless mesh network using Nordic wireless on SJOne boards. Each SJOne board acts as a node in the wireless mesh network. Features such as self-healing, shortest path routing, address nodes with auto-replies, and node participation are implemented to as to make the communication more reliable.

Objectives & Introduction

The wireless mesh network is achieved through the built-in Nordic Wireless interface. Each board acts as a node in the wireless mesh network which sends and receives information. The following objectives are to be implemented:

• Self-healing
• Shortest path routes
• Address nodes with auto-retries
• Each node participation

Mesh networks play an important part in the Internet of Things(IoT). Mesh networks can use a full mesh topology or a partial mesh topology. In full mesh topology, each node is connected to every other node in the network and in a partial mesh topology at least one node is connected to every other node and the rest of the nodes are connected to the nodes that they frequently exchange data with. Wired mesh network pose several constraints. Each node in the network has to be physically connected to every other node. The advancement of wireless mesh networks simplifies this approach.

A Wireless Mesh Network(WMN) is a communication network made up of radio nodes organized in a mesh topology. It was originally developed for the military communication. A typical wireless mesh network consists of mesh clients, mesh routers, and gateways. In this project the SJOne boards are the mesh clients. Mesh routers route traffic from the gateways, which can happen over the internet. A mesh cloud comprises of the area covered by the radio nodes working as a single network. A mesh network is highly reliable, during transmission if a node fails, the data is sent to the other node through a redirected path. The data is transmitted from one node to other in hops through the intermediate nodes. Each intermediate nodes maintains a routing table which includes information about the network topology, destination node, source node and next hop. A routing table is a database which keeps track of the path and assists the intermediate node in delivering the information from source to the destination.

Self-healing is a technique in which a new connection is formed between the nodes in case of a failure such as a node moving out of scope due to external or internal disturbances. This ensures that the data is transmitted to the destination node through a new path even if there is any conflict in the established path. This technique is demonstrated through a gif in figure 3. The node in red is the node which is destroyed, a communication link is established between the other two nodes ensuring reliable transmission of data.

Shortest path routes is a technique in which the message from node A to node B is delivered through the shortest possible path in the network. Suppose in the mesh network shown in figure 1, if node A wants to send the data to node C, it will directly send it to C instead of routing it through B or D.

Address nodes with auto-retries is a technique in which a node re-sends the packet if it doesn't get an acknowledgement from the destination node. The number maximum number of re-transmits, delay for a single transmit and delay from one transmission to the other are fully configurable.

Each node participation is a technique through which the nodes in the network actively participate in the network to deliver the packets. This is essential for self-healing.

Team Members & Responsibilities

1. Akhil Bhargav Josyabhatla

• Software implementation

2. Dheeraj Dake

• Software implementation

3. Manideep Kurumella

• Software implementation

4. Vishnu Vardhana Reddy Mandalapu

• Software implementation

Schedule

Show a simple table or figures that show your scheduled as planned before you started working on the project. Then in another table column, write down the actual schedule so that readers can see the planned vs. actual goals. The point of the schedule is for readers to assess how to pace themselves if they are doing a similar project.

Week	Dates	Challenges	Comments
1	3/31 - 4/7	Mesh network overview	Completed
2	4/7 - 4/14	ANT network overview	Completed
3	4/14 - 4/21	To test communication between the boards using Nordic wireless	Completed
4	4/21 - 4/28	To send packets using addressing techniques	Completed
5	4/28 - 5/5	To test the shortest path using all possible configurations	To be done
6	5/5 - 5/12	Implement self healing and re-transmission mechanisms	To be done
7	5/12 - 5/19	Testing	To be done
8	5/19 - 5/25	More testing and final demo	To be done

Parts List & Cost

Item	Price	Quantity	Price
SJ One Board	$80	4	$320
Antenna	$3	4	$12
Total			$332

Design & Implementation

The design section can go over your hardware and software design. Organize this section using sub-sections that go over your design and implementation.

Hardware Design

Wireless mesh network is achieved using Nordic nRF24L01 transceiver. The hardware schematic of the chip is taken from the datasheet. The pins CE, SCN, SCK, MOSI, MISO and IRQ are connected to the CPU pins. The electrical connections between the CPU and wireless transceiver are taken from SJOne_lpc1758_rev4.pdf. The detailed hardware schematic is shown in figure 4. The block diagram of nRF24L01 from the datasheet is shown in figure 5.

Hardware Interface

The hardware interface consists of 4 SJOne boards that are powered via laptops through a USB. Antennas are attached for increasing the wireless range. The nordic wireless communicates with the LPC 1769 CPU via SPI bus. The pins that are used for establishing the communication between the nordic wireless and CPU are shown in the table below.

Nordic pins	CPU pins	Description
CE	P1.24	Chip enable activates RX or TX mode
CSN	P0.16	SPI Chip select
SCK	P0.15	SPI Clock
MOSI	P0.18	SPI Slave Data Input
MISO	P0.17	SPI Slave Data Output, with tri-state option
IRQ	P0.22	Maskable interrupt pin, active low

An air data rate of 2Mbps is chosen for sending and receiving the data between the boards. Nordic wireless nRF24lo1 uses GFSK which is Gaussian Frequency Shift Keying which is a technique in which the positive and negative frequency deviations are smoothed by a Gaussian filter. This technique reduces the spectral width, making the effective bandwidth smaller which improves the quality of the transmitted signal. This ensures that the channels intersymbol interference is under control. In RF its sole purpose is to make the signal fit in its frequency band.

Software Design

The wireless mesh network we are designing follows the software hierarchy mentioned in figure 6. It has 4 layers. The upper level layer being the mesh layer and the lower level being the hardware layer.

1. Mesh Layer This is a high level layer. The routing tables needed to maintain the source address and hop count, macros and other initialization's are defined in this layer. The network discovery is done in this layer. The packet is formed and sent from this layer to the lower layers. This layer takes care of the packet collision and implements self-healing, shortest path techniques for reliable communication between the nodes. It features automatic re-transmission of the packets in case of NACK. The number of auto retries are user configurable.

2. Packet Layer This layer defines the interface between Nordic and mesh layer to receive and send packets. it receives 32 bytes data from lower layer and passes to upper layer and vice versa. It is also responsible to Nordic RF module. The nordic chip is initialized in this layer. The send and receive functions are implemented in this layer. The send function takes data and length as arguments and passes them to the Nordic. The receive function receives data and length from Nordic.

3. Nordic Layer This layer is responsible for exchanging the data packets through the SPI bus with the hardware layer for transmission. This layer sets the air data rate, channel frequency and payload. The operating modes of the Nordic wireless are implemented in this layer.

4. Hardware Layer This is the lower most layer in the hierarchy and initializes the nRF24L01+ transreceiver. The respective board I/O for the Nordic wireless are set and the SPI bus interface is initialized. The hardware layer is responsible for the transmission of the packets over the air between the nodes for communication.

Implementation

The nRF24L01+ is a single chip transceiver which operates on a ISM frequency in the range 2.400-2.4835 GHz. It is connected to the LPC 1758 using the electrical specifications in the figure 4. The communication between the CPU and transceiver is established via the SPI bus. The internal FIFO’s ensure a smooth data flow between the radio front end and the systems MCU. It uses GFSK(Gaussian Frequency Shift Keying) modulation. In this project an air data rate of 1 Mbps is chosen. Each node is given a unique address so as to distinguish one from another. An RF channel frequency of 2.400 GHz is chosen for communication. The Nordic wireless has three 32 bytes tx and rx FIFO’s. The ANT pins provide a balanced RF output to the antenna.

In a mesh network multiple nodes transmit data simultaneously. The data is constantly exchanged between the nodes. Since all the nodes exchange the data on the same frequency, this creates collisions. To avoid collision in our mesh network, ALOHA protocol is used. The idea behind ALOHA is that, let the nodes transmit their packets at once and let there be collisions. If a collision occurs, the packets which are lost are re-transmitted after a random amount of time. The packet transmission will be eventually successful. The mesh layer is implemented as per the software hierarchy shown in figure 7. The definition of each function is explained below.

1. mesh_init()

• The routing tables are initialized here. It initially broadcasts hello packets to determine the nodes which are in its communication range.

2. mesh_service()

• This is the high level layer which deals with the transmission and reception of packet. It calls process_data packet() and process_hello_packet() according to the received packet type.

3. process_data_packet()

• This processes the data packet and checks whether the address in the packet is equal to the address of the node which received it. If there is a match the node keeps the packet and the transmission ends, otherwise it broadcasts the packets to the nodes within the next hop count.

4. process_hello_packet()

• This processes the hello packet which is used to determine all the nodes in its communication range. The routing table gets updated if there is a node malfunction.

5. frame_data_packet()

• This contains a command handler which asks the user to enter the destination node address to which the data is to be sent. It then frames the packet according to the payload and sends the packet to the destination using the route table.

6. frame_hello_packet()

• It sends the routing information into the payload and broadcasts it.

Testing & Technical Challenges

Describe the challenges of your project. What advise would you give yourself or someone else if your project can be started from scratch again? Make a smooth transition to testing section and described what it took to test your project.

Include sub-sections that list out a problem and solution, such as:

My Issue #1

1. Huge packet loss while transmitting packets using Nordic wireless

Conclusion

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Project Video

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Project Source Code

• Sourceforge Source Code Link

References

Acknowledgement

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References Used

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Appendix

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