Z-wave refers to a radio system used by many smart home devices. Smart home is essential technology of the 21st century that can help you always to connect one end of your home system to the other. The Z-Wave and ZigBee technologies are two major standards that can be used for smart devices, smart lighting, automation control, heating and security equipment.
Z-wave was initially developed in 1999 by a Danish company known as Zensys. It is a simple, economical and versatile substitute for home automation systems. Since its development, it has rapidly attained the support of more than 700 home electronics brands and companies, such as Huawei, ADT, Samsung Intelligence, LG, General Electric, August, SMIC, and Ingersoll Rand. Currently, there are over 2,600 various Z-Wave certified products on the market, all built for interoperation.
The Z-wave network is specially built to link smart home devices and smart hubs. The Z-wave technology can be found in smart switches, thermostats, sensors, etc. It can connect devices in an appropriate-sized house, although it uses much less power than regular Bluetooth and Wi-Fi.
Like Zigbee technology, Z-Wave connects to devices using a grid topology. This implies that rather than every device having to directly link to a router or hub, devices using the Z-Wave technology can transmit data packets to and fro between the devices. Therefore, when the distance between a Z-Wave bulb and hub is large, the signal can still transmit to its desired location, passing through the sensors and the devices.
This arrangement makes Z-Wave more flexible, even slightly slower than Wi-Fi. Its network range grows significantly when many Z-Wave devices are installed. Moreover, the installment of many devices makes the Z-Wave technology more robust as there are many techniques for transmitting data packets from one point to another.
The operating frequencies of Z-Wave range from 800 to 900 MHz, whereas Zigbee can even fully function at 2.4 GHz. This implies that devices enabled with Z-Wave have a much lower rate of data transmission than devices enabled with ZigBee. Furthermore, Z-wave supports lower data transmission of 9.6-10 KBPS, whereas Zigbee can support transmissions of up to 250 KBPS.
Nevertheless, Z-Wave devices have a very small possibility of external interference, whereas Zigbee devices have a more significant possibility. Z-wave and Zigbee technologies add devices to their networks by implementing mesh network topologies. Only less than 232 devices can be supported in a Z-wave network, but Zigbee networks can support over 65,000 devices. In the case of a homeowner, having even 232 units is more than enough needed to run a home entirely.
The AES 128-bit encryption is used securely with no hacking in both Z-Wave and ZigBee networks. With absolute security being a contradiction, it is essential to realize that both networks adopt similar methods to end-user security. Additionally, the range of Z-Wave devices is about 30 meters, whereas Zigbee devices have a limited range of fewer than 20 meters.
Besides, it is essential to know that the Zigbee Consortium runs and manages the available standard Zigbee technology, whereas the Sigma devices company privately owns the Z-Wave technology. Hence they have tighter controls that guarantee device compatibility with many controllers.
Wi-Fi has multiple advantages when used for home automation. Wi-Fi devices can be placed anywhere in a room without worrying about tripping over the ropes required to run. Systematizing with a Wi-Fi network can help free up router ports for those other devices when one or more devices are router-hardwired.
Home automation systems based on the Wi-Fi network are as dependable as wireless networks. Automation reduces whenever a Wi-Fi network frequently goes down.
On the question of whether Z-Wave is more suitable for automation than Wi-Fi? Believe it or not, it is easier to set up a Z-Wave network than Wi-Fi as there are no worries about it meddling with a home Wi-Fi signal.
Most Z-Wave devices can directly and quickly add new devices to a home system as they can automatically detect each other. Moreover, the Z-Wave network is more flexible, and thousands of various devices can run on Z-Wave frequencies. Hence, it is easier to establish the best device for your necessities.
Compatibility is one more thing the Z-Wave network can’t contest with Wi-Fi. Devices using the Z-wave network are backward compatible. Thus, older devices are compatible with the present system, and any new devices developed are expected to be compatible with the already existing Settings.
Home automation systems can be set up using both Z-Wave and Wi-Fi networks. From security systems to smart appliances to lighting and garage door openers, both networks can be used to connect to nearly any electronic device.
If your home already has an existing Wi-Fi network, no extra setup or cost is required. Wi-Fi-enabled home automation devices are cheaper than Z-Wave-enabled devices, although various problems arise when too many devices are connected to a Wi-Fi network simultaneously.
Z-wave systems are costlier, but they eliminate issues relating to interference as they work at a relatively different wavelength than Wi-Fi signals.
The Z-wave technology was initially designed for wireless control of smart homes, concentrating on business and residential lighting control. It changes some stand-alone devices to smart networking devices, thus facilitating wireless control and monitoring. The Z-Wave technology is extensively used for smoke detectors, remote control, lighting control, security and climate control, appliances, door locks, and security sensors. Moreover, it can also be used in smart meters to offer the data consumption rate for home HVAC monitoring.
The Z-Wave network is indeed very secure. It assigns every device a unique network ID. Since every control system has a different ID that is automatically controlled, no external party can control the devices.
Whenever an extra security level is required, such as door locks and other security devices, Z-Wave secures and protects the device’s data using a more advanced AES128 encryption technique. The Z-Wave AES encryption method is used by most products running on a Z-Wave network.
Short control data is consistently transferred between node units. From bottom to top, its protocols are categorized into five layers: the physical layer, MAC layer, transport layer, routing layer, and application layer. The role of the MAC layer is to establish, maintain, and terminate any wireless information connections between devices. Altogether, it carries out frame verification, controls channel access, and reserves the management of time slots.
The media layer adopts the mechanisms of Collision avoidance (CSMA crocodile CA) and carrier sense multiple Access to enhance the dependability of data transmission. It also stops other nodes from transferring signals when nodes are available to share information. On the other hand, the transport layer is primarily used to offer consistent data broadcast between nodes. Its key roles are; frame verification, retransmission, flow control, and frame verification.
The routing layer controls the data frame’s routing between nodes. Also, it makes sure that data frames can be transferred repetitively among various nodes, scans the topology of a network, and maintains the routing table. The application layer is liable for the instruction execution and decryption in the Z-Wave network. Its primary roles are; HomeID and No ID assignment, Manchester decoding, network controller replication, instruction recognition, and payload control for received and transferred frames.
Z-wave is a wireless technology that emphasizes on application of low-rate. Its rates of transmission are between 9.6kbit /s and 40Kbit/s. The prior is more than satisfactory for transferring control commands, while the latter can offer more advanced network security mechanisms. It has a flexible operating frequency band in the ISM band of 900MHz, 908.42MHz in the United States, and 868.42MHz in Europe. Only relatively few devices effectively operate in these bands.
Zigbee and Bluetooth use the 2.4GHz band, which is becoming progressively crowded, and the intrusion is unavoidable. Therefore, the Z-Wave technology warrants reliable communication, although its power consumption rate is relatively lower. It incorporates a Frequency-Shift Keying (FSK) mode of wireless communication that is more suitable for smart home networks. Nodes powered on batteries are primarily kept in a sleep-mode state, where they frequently wake, to monitor if there is any information it needs to receive. The nodes use two ordinary No. 7 batteries lasting up to 10 years.
It ensures the application has long-term stability, thus enabling the user to evade the concern of recurrent charging and replacing the electric pool. Z-Wave has a less complex system than ZigBee and is smaller than the Bluetooth network. It requires small storage, and its protocol is simple. The protocol of a standard Z-Wave module is captured by an in-built 32KB flash memory, whereas the same ZigBee module needs about 128KB to use. Bluetooth requires a relatively big module. Hence, Z-Wave modules are less costly than ZigBee or Bluetooth modules.
The Z-Wave network supports a maximum of 4 level routes and has a single capability of about 232 nodes, far less than ZigBee’s 65,535. Z-Wave cannot build large-scale networks in a universal application compared to ZigBee. Also, the Z-Wave network can use virtual node technology to communicate with other kinds of networks.
The MAC layer controls the wireless medium in the Z-wave network. The Manchester coding is adopted by the data stream, which consists of the frame head, frame tail, frame data, and preceding code. Frame data comprises a frame part that is passed to the transport layer. All information is transmitted through a little-endian mode.
Although the MAC layer is autonomous of the wireless frequency, medium, and modulation technique, it necessitates that the complete binary signal or the frame data is easily obtainable from the Manchester encoded or decoded bit streams when receiving information. An 8-bit data block is used to transmit data. The Most Significant Bit (MSB) is the first Bit of data to be transmitted. The data is encrypted in Manchester to attain a DC-free signal.
In the MAC layer, a conflict avoidance mechanism prevents nodes from transferring information when other nodes send data. The collision avoidance mechanism is implemented by putting nodes that are not transferring information into receive mode and suspending communications in case the MAC layer is in the receiving phase. All kinds of nodes have an active collision avoidance mechanism. Frame transmissions are always delayed by a few milliseconds whenever the medium is busy.
The CSMA/CA forms the core of the MAC collision avoidance mechanism. The CSMA/CA comprises three mechanisms; the inter-frame interval, carrier listening, and random backoff. Every node uses the distributed Access algorithm of Carrier Sense Multiple Access (CSMA) to make it fully complete for the channel to attain the transmission accurately. The ACK (Acknowledgement) mechanism or the twice-handshake mechanism is used in the CSMA/CA mode. The ACK frame is immediately sent whenever the receiver obtains the correct frame. The frame is successfully sent when the sender receives the Acknowledgement frame.
Data is transmitted in a delayed transmission when the frame interval is smaller than or equal to the media idle time. The carrier listening mechanism forms the basis of CSMA/CA. Physical carrier monitoring is done at the physical layer by sensing the antenna’s valid signals. The detection of valid signals shows that the physical carrier monitoring has considered the channel busy. Moreover, MAC carrier monitoring is accomplished at the MAC layer by sensing the MAC frame’s inter-tenacity domain.
Information is broadcasted only when there is an idle channel. A busy channel executes the backoff algorithm where the channel is redetected to evade crashes between the media shared. Multiple nodes are waiting for the medium. All nodes send data when the medium is idle, thus leading to multiple collisions. Thus, CSMA/CA controls the sending of frames of every node using the random backoff time.
The transport layer is used to transmit reliable data between nodes. It comprises frame verification, flow control, retransmission, and frame confirmation. Moreover, the transport layer is consists of three types of frames. They are;
Unicast frame – It is directed to a definite node. The Unicast frame replies with an ACK reply frame when the target node effectively receives the frame. On the other hand, the Unicast frame is resent once damaged or lost. The retransmission frame encounters random delays to evade collisions with other systems. The unexpected delay should always be constant with the maximum length of the frame transferred and the duration taken to obtain the reply frame. Unicast frames also optionally switch off the reply mechanism in systems that don’t need a dependable transmission. A reply frame is a kind of unicast frame in the Z-Wave network with a data field of length O.
Multicast frames – Multicast frames are transferred in the network from nodes 1 to 232. The multicast frame destination specifies all destination nodes without transmitting a discrete frame to every node. Multicast frames cannot be used in systems that need reliable communications as they do not respond actively. When multicast frames need dependability, unicast frames should follow them.
Broadcast frame – The broadcast frame is transferred to all network nodes. The frame does not receive a response from any node. Similar to the multicast frame, the broadcast frame cannot be used in systems that need reliable communication. Moreover, the broadcast frame must be followed by a unicast frame in case the broadcast frame requires dependability.
Devices like printers, desktops, laptops, and microwaves consume power even when they are not in usage, thus representing almost 20% of all monthly energy bills in a home. It is constantly hard to switch off the thermostat when moving out of the house. Z-Wave products can help you quickly go green as they are built to save energy and cost at your home daily.
Z-wave products are different from the rest as they interact via a cohesive mesh network that permits the access and connection of all devices through a single portable application. Using an application that carefully manages your whole smart home, you can switch off all devices that consume more energy in less than a second from almost any location. Some of the ways the Z-Wave technology can be used to minimize energy bills in homes are;
The Z-wave technology was developed by a Danish company known as Zensys. Two Danish engineers established the company in the late 1990s. Zensys has grown from creating home automation solutions to being a provider of technical communications. The company offers technical support to enterprises designing solutions for interoperable control. Vendors worldwide recognize the Z-wave technology for its interoperability and reliability, thus building the largest compatible ecosystem.
The Zensys company brought the first hardware into the market in 2003. It combined a standard transceiver and a microcontroller (Atmel). The expansion of this hardware platform has led to the growth of subsequent chip generations 100 (2003), 200 (2005), 300 (2007), 400 (2009) and the latest 500 (2012).
Another milestone in the history of Z-Wave was realized in 2005 after the formation of the Z-Wave Alliance. This alliance aims to gather companies that manufacture products compatible with the Z-Wave technology. By 2008, over 100 manufacturing companies had joined the alliance. The Z-Wave Alliance has increasingly sustained to improve the standards and manage global promotional events like trade shows.
The Z-Wave Consortium is also responsible for retaining the interoperability of several devices based on the Z-Wave protocol. This is attained through establishing a critical verification system and a valuable pre-packaged source code base to ensure that the devices pinned with a Z-Wave logo meet the 3 requirements of the Z-Wave Alliance. These requirements are; excellent efficiency, compliance with specifications of the communication protocol, and reliable user experience.
The US market is the largest target for Z-wave products. Over 70% of those using Z-Wave products are from the United States, while the other 25% are in Europe and 5% are based in China. With the US being a comparatively developed nation, many individuals in the country have promptly embraced the Z-Wave technology. This is because most houses in American cities are big; hence it is challenging to move from one room to the other, switching off the lights.
Moreover, since the United States is a big country, safety is its primary concern; hence they have very mature security system services. In security enterprises, the security downstream and upstream of the whole chain are perfect, irrespective of whether it is a construction, product, or after-sales service. Based on this, smart home systems can enhance significant enactments for security enterprises. Smart homes are more prevalent in the United States as people living there are more than happy to embrace this new technology in their homes.
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