image-20220610095606-1.png

Contents:

1.  Introduction

1.1 ​ What is LoRaWAN LiDAR ToF Distance Sensor

 

The Dragino LLDS12 is a LoRaWAN LiDAR ToF (Time of Flight) Distance Sensor for Internet of Things solution. It is capable to measure the distance to an object as close as 10 centimeters (+/- 5cm up to 6m) and as far as 12 meters (+/-1% starting at 6m)!. The LiDAR probe uses laser induction technology for distance measurement.

The LLDS12 can be applied to scenarios such as horizontal distance measurement, parking management system, object proximity and presence detection, intelligent trash can management system, robot obstacle avoidance, automatic control, sewer, etc.

It detects the distance between the measured object and the sensor, and uploads the value via wireless to LoRaWAN IoT Server.

The LoRa wireless technology used in LLDS12 allows device to send data and reach extremely long ranges at low data-rates. It provides ultra-long range spread spectrum communication and high interference immunity whilst minimizing current consumption.

LLDS12 is powered by 8500mAh Li-SOCI2 battery, it is designed for long term use up to 5 years.

Each LLDS12 is pre-load with a set of unique keys for LoRaWAN registrations, register these keys to local LoRaWAN server and it will auto connect after power on.

1654826306458-414.png

​1.2  Features

  • LoRaWAN 1.0.3 Class A
  • Ultra-low power consumption
  • Laser technology for distance detection
  • Operating Range - 0.1m~12m①
  • Accuracy - ±5cm@(0.1-6m), ±1%@(6m-12m)
  • Monitor Battery Level
  • Bands: CN470/EU433/KR920/US915/EU868/AS923/AU915/IN865
  • AT Commands to change parameters
  • Uplink on periodically
  • Downlink to change configure
  • 8500mAh Battery for long term use

1.3  Probe Specification

  • Storage temperature :-20℃~75℃
  • Operating temperature - -20℃~60℃
  • Operating Range - 0.1m~12m①
  • Accuracy - ±5cm@(0.1-6m), ±1%@(6m-12m)
  • Distance resolution - 5mm
  • Ambient light immunity - 70klux
  • Enclosure rating - IP65
  • Light source - LED
  • Central wavelength - 850nm
  • FOV - 3.6°
  • Material of enclosure - ABS+PC
  • Wire length - 25cm

1.4  Probe Dimension

1654827224480-952.png

1.5 ​ Applications

  • Horizontal distance measurement
  • Parking management system
  • Object proximity and presence detection
  • Intelligent trash can management system
  • Robot obstacle avoidance
  • Automatic control
  • Sewer

1.6 Pin mapping and power on

1654827332142-133.png

2. Configure LLDS12 to connect to LoRaWAN network

2.1 How it works

The LLDS12 is configured as LoRaWAN OTAA Class A mode by default. It has OTAA keys to join LoRaWAN network. To connect a local LoRaWAN network, you need to input the OTAA keys in the LoRaWAN IoT server and power on the LLDS12. It will automatically join the network via OTAA and start to send the sensor value. The default uplink interval is 20 minutes.

In case you can’t set the OTAA keys in the LoRaWAN OTAA server, and you have to use the keys from the server, you can use AT Commands to set the keys in the LLDS12.

2.2 ​Quick guide to connect to LoRaWAN server (OTAA)

Following is an example for how to join the TTN v3 LoRaWAN Network. Below is the network structure; we use the LG308  as a LoRaWAN gateway in this example. 

1654827857527-556.png

The LG308 is already set to connected to TTN network , so what we need to now is configure the TTN server.

Step 1: Create a device in TTN with the OTAA keys from LSPH01.

Each LSPH01 is shipped with a sticker with the default device EUI as below:

image-20220607170145-1.jpeg

You can enter this key in the LoRaWAN Server portal. Below is TTN screen shot:

Register the device

1654592600093-601.png

Add APP EUI and DEV EUI

1654592619856-881.png

Add APP EUI in the application

1654592632656-512.png

Add APP KEY

1654592653453-934.png

Step 2: Power on LSPH01

Put a Jumper on JP2 to power on the device. ( The Switch must be in FLASH position).

image-20220607170442-2.png

Step 3: The LSPH01 will auto join to the TTN network. After join success, it will start to upload messages to TTN and you can see the messages in the panel.

1654592697690-910.png

2.3 ​Uplink Payload

LSPH01 will uplink payload via LoRaWAN with below payload format:  

Uplink payload includes in total 11 bytes.

Normal uplink payload:

Size (bytes)

2222111
ValueBATSoil pHSoil TemperatureReserve

1654592721645-318.png

2.3.1 Battery Info

Check the battery voltage for LSPH01.

Ex1: 0x0B45 = 2885mV

Ex2: 0x0B49 = 2889mV

2.3.2 DS18B20 Temperature sensor

This is optional, user can connect external DS18B20 sensor to the +3.3v, 1-wire and GND pin . and this field will report temperature.

Example:

If payload is: 0105H:  (0105 & FC00 == 0), temp = 0105H /10 = 26.1 degree

If payload is: FF3FH :  (FF3F & FC00 == 1) , temp = (FF3FH - 65536)/10 = -19.3 degrees.

2.3.3 Soil pH

Range: 0 ~ 14 pH

Example:

 0x02B7(H) = 695(D) = 6.95pH

2.3.4 Soil Temperature

Get Soil Temperature  

Example:

If payload is: 0105H:  (0105 & FC00 == 0), temp = 0105H /10 = 26.1 degree

If payload is: FF3FH :  (FF3F & FC00 == 1) , temp = (FF3FH - 65536)/10 = -19.3 degrees.

2.3.5 Interrupt Pin

This data field shows if this packet is generated by interrupt or not. Click here for the hardware and software set up.

Example:

0x00: Normal uplink packet.

0x01: Interrupt Uplink Packet.

2.3.6 Message Type

For a normal uplink payload, the message type is always 0x01.

Valid Message Type:

Message Type CodeDescriptionPayload
0x01Normal UplinkNormal Uplink Payload
0x02Reply configures infoConfigure Info Payload
0x03Reply Calibration InfoCalibration Payload

2.3.7 Decode payload in The Things Network

While using TTN network, you can add the payload format to decode the payload.

1654592762713-715.png

The payload decoder function for TTN is here:

2.4 Uplink Interval

The LSPH01 by default uplink the sensor data every 20 minutes. User can change this interval by AT Command or LoRaWAN Downlink Command. See this link: Change Uplink Interval

2.5 ​Show Data in DataCake IoT Server

DATACAKE provides a human friendly interface to show the sensor data, once we have data in TTN, we can use DATACAKE to connect to TTN and see the data in DATACAKE. Below are the steps:

 

Step 1: Be sure that your device is programmed and properly connected to the network at this time.

Step 2: To configure the Application to forward data to DATACAKE you will need to add integration. To add the DATACAKE integration, perform the following steps:

1654592790040-760.png

1654592800389-571.png

Step 3: Create an account or log in Datacake.

Step 4: Create LSPH01 product.

1654592819047-535.png

1654592833877-762.png

1654592856403-259.png

Step 5: add payload decode

1654592878525-845.png

1654592892967-474.png

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After added, the sensor data arrive TTN, it will also arrive and show in Mydevices.

1654592917530-261.png

2.6 Installation and Maintain

2.6.1 Before measurement

If the LSPH01 has more than 7 days not use or just clean the pH probe. User should put the probe inside pure water for more than 24 hours for activation. If no put in water, user need to put inside soil for more than 24 hours to ensure the measurement accuracy.  

2.6.2 Measurement

Measurement the soil surface:

1654592946732-634.png

Choose the proper measuring position. Split the surface soil according to the measured deep.

Put pure water, or rainwater to make the soil of measurement point to moist mud. Remove rocks or hard things.

Slowly insert the probe to the measure point. Don’t use large force which will break the probe. Make sure not shake when inserting.

Put soil over the probe after insert. And start to measure.

 

Measurement inside soil:

Dig a hole with diameter > 20CM.

Insert the probe inside, method like measure the surface.

2.6.3 Maintain Probe

  1. pH probe electrode is fragile and no strong. User must avoid strong force or hitting it.

  2. After long time use (3~ 6  months). The probe electrode needs to be clean; user can use high grade sandpaper to polish it or put in 5% hydrochloric acid for several minutes. After the metal probe looks like new, user can use pure water to wash it.

  3. Probe reference electrode is also no strong, need to avoid strong force or hitting.

  4. User should keep reference electrode wet while not use.

  5. Avoid the probes to touch oily matter. Which will cause issue in accuracy.

  6. The probe is IP68 can be put in water.

     

2.7 Calibration

User can do calibration for the probe. It is limited to use below pH buffer solution to calibrate: 4.00, 6.86, 9.18. When calibration, user need to clean the electrode and put the probe in the pH buffer solution to wait the value stable ( a new clean electrode might need max 24 hours to be stable).

After stable, user can use below command to calibrate.

image-20220607171149-4.png

Calibration Payload

Size (bytes)

11171
Value

PH4

Calibrate value

PH6.86 Calibrate value

PH9.18

Calibrate value

Reserve

Message Type

Always 0x03

User can also send 0x14 downlink command to poll the current calibration payload.

image-20220607171416-7.jpeg

  • Reply to the confirmation package: 14 01
  • Reply to non-confirmed packet: 14 00

2.8 Frequency Plans

The LSPH01 uses OTAA mode and below frequency plans by default. If user want to use it with different frequency plan, please refer the AT command sets.

2.8.1 EU863-870 (EU868)

Uplink:

868.1 - SF7BW125 to SF12BW125

868.3 - SF7BW125 to SF12BW125 and SF7BW250

868.5 - SF7BW125 to SF12BW125

867.1 - SF7BW125 to SF12BW125

867.3 - SF7BW125 to SF12BW125

867.5 - SF7BW125 to SF12BW125

867.7 - SF7BW125 to SF12BW125

867.9 - SF7BW125 to SF12BW125

868.8 - FSK

 

Downlink:

Uplink channels 1-9 (RX1)

869.525 - SF9BW125 (RX2 downlink only)

2.8.2 US902-928(US915)

Used in USA, Canada and South America. Frequency band as per definition in LoRaWAN 1.0.3 Regional document.

To make sure the end node supports all sub band by default. In the OTAA Join process, the end node will use frequency 1 from sub-band1, then frequency 1 from sub-band2, then frequency 1 from sub-band3, etc to process the OTAA join.

After Join success, the end node will switch to the correct sub band by:

  • Check what sub-band the LoRaWAN server ask from the OTAA Join Accept message and switch to that sub-band
  • Use the Join successful sub-band if the server doesn’t include sub-band info in the OTAA Join Accept message ( TTN v2 doesn't include)

2.8.3 CN470-510 (CN470)

Used in China, Default use CHE=1

Uplink:

486.3 - SF7BW125 to SF12BW125

486.5 - SF7BW125 to SF12BW125

486.7 - SF7BW125 to SF12BW125

486.9 - SF7BW125 to SF12BW125

487.1 - SF7BW125 to SF12BW125

487.3 - SF7BW125 to SF12BW125

487.5 - SF7BW125 to SF12BW125

487.7 - SF7BW125 to SF12BW125

 

Downlink:

506.7 - SF7BW125 to SF12BW125

506.9 - SF7BW125 to SF12BW125

507.1 - SF7BW125 to SF12BW125

507.3 - SF7BW125 to SF12BW125

507.5 - SF7BW125 to SF12BW125

507.7 - SF7BW125 to SF12BW125

507.9 - SF7BW125 to SF12BW125

508.1 - SF7BW125 to SF12BW125

505.3 - SF12BW125 (RX2 downlink only)

2.8.4 AU915-928(AU915)

Frequency band as per definition in LoRaWAN 1.0.3 Regional document.

To make sure the end node supports all sub band by default. In the OTAA Join process, the end node will use frequency 1 from sub-band1, then frequency 1 from sub-band2, then frequency 1 from sub-band3, etc to process the OTAA join.

 

After Join success, the end node will switch to the correct sub band by:

  • Check what sub-band the LoRaWAN server ask from the OTAA Join Accept message and switch to that sub-band
  • Use the Join successful sub-band if the server doesn’t include sub-band info in the OTAA Join Accept message ( TTN v2 doesn't include)

2.8.5 AS920-923 & AS923-925 (AS923)

Default Uplink channel:

923.2 - SF7BW125 to SF10BW125

923.4 - SF7BW125 to SF10BW125

 

Additional Uplink Channel:

(OTAA mode, channel added by JoinAccept message)

 

AS920~AS923 for Japan, Malaysia, Singapore:

922.2 - SF7BW125 to SF10BW125

922.4 - SF7BW125 to SF10BW125

922.6 - SF7BW125 to SF10BW125

922.8 - SF7BW125 to SF10BW125

923.0 - SF7BW125 to SF10BW125

922.0 - SF7BW125 to SF10BW125

 

AS923 ~ AS925 for Brunei, Cambodia, Hong Kong, Indonesia, Laos, Taiwan, Thailand, Vietnam:

923.6 - SF7BW125 to SF10BW125

923.8 - SF7BW125 to SF10BW125

924.0 - SF7BW125 to SF10BW125

924.2 - SF7BW125 to SF10BW125

924.4 - SF7BW125 to SF10BW125

924.6 - SF7BW125 to SF10BW125

 

Downlink:

Uplink channels 1-8 (RX1)

923.2 - SF10BW125 (RX2)

2.8.6 KR920-923 (KR920)

Default channel:

922.1 - SF7BW125 to SF12BW125

922.3 - SF7BW125 to SF12BW125

922.5 - SF7BW125 to SF12BW125

 

Uplink: (OTAA mode, channel added by JoinAccept message)

922.1 - SF7BW125 to SF12BW125

922.3 - SF7BW125 to SF12BW125

922.5 - SF7BW125 to SF12BW125

922.7 - SF7BW125 to SF12BW125

922.9 - SF7BW125 to SF12BW125

923.1 - SF7BW125 to SF12BW125

923.3 - SF7BW125 to SF12BW125

 

Downlink:

Uplink channels 1-7(RX1)

921.9 - SF12BW125 (RX2 downlink only; SF12BW125 might be changed to SF9BW125)

2.8.7 IN865-867 (IN865)

Uplink:

865.0625 - SF7BW125 to SF12BW125

865.4025 - SF7BW125 to SF12BW125

865.9850 - SF7BW125 to SF12BW125

 

Downlink:

Uplink channels 1-3 (RX1)

866.550 - SF10BW125 (RX2)

2.9 LED Indicator

The LSPH01 has an internal LED which is to show the status of different state. 

  • The sensor is detected when the device is turned on, and it will flash 4 times quickly when it is detected.
  • Blink once when device transmit a packet.

2.10 ​Firmware Change Log

Firmware download link:

http://www.dragino.com/downloads/index.pHp?dir=LoRa_End_Node/LSPH01/Firmware/

Firmware Upgrade Method: Firmware Upgrade Instruction

3.  LiDAR ToF Measurement

3.1  Principle of Distance Measurement

The LiDAR probe is based on TOF, namely, Time of Flight principle. To be specific, the product emits modulation wave of near infrared ray on a periodic basis, which will be reflected after contacting object. The product obtains the time of flight by measuring round-trip phase difference and then calculates relative range between the product and the detection object, as shown below.

file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image001.png

3.2  Distance Measurement Characteristics

With optimization of light path and algorithm, The LiDAR probe has minimized influence from external environment on distance measurement performance. Despite that, the range of distance measurement may still be affected by the environment illumination intensity and the reflectivity of detection object. As shown in below:

file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image002.png

①Represents the detection blind zone of The LiDAR probe, 0-10cm, within which the output data is unreliable.

②Represents the operating range of The LiDAR probe detecting black target with 10% reflectivity, 0.1-5m.

③Represents the operating range of The LiDAR probe detecting white target with 90% reflectivity, 0.1-12m.

Vertical Coordinates: Represents the radius of light spot for The LiDAR probe at the different distances. The diameter of light spot depends on the FOV of The LiDAR probe (the term of FOV generally refers to the smaller value between the receiving angle and the transmitting angle), which is calculated as follows:

file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image003.png

In the formula above, d is the diameter of light spot; D is detecting range; β is the value of the receiving angle of The LiDAR probe, 3.6°. Correspondence between the diameter of light spot and detecting range is given in Table below.

file:///C:/Users/93456/AppData/Local/Temp/msohtmlclip1/01/clip_image004.png

If the light spot reaches two objects with different distances, as shown in Figure 3, the output distance value will be a value between the actual distance values of the two objects. For a high accuracy requirement in practice, the above situation should be noticed to avoid the measurement error.

3.3  Notice of usage:

Possible invalid /wrong reading for LiDAR ToF tech:

  • Measure high reflectivity object such as: Mirror, Smooth ceramic tile, static milk surface, will have possible wrong readings.
  • While there is transparent object such as glass, water drop between the measured object and the LiDAR sensor, the reading might wrong.
  • The LiDAR probe is cover by dirty things; the reading might be wrong. In this case, need to clean the probe.
  • The sensor window is made by Acrylic. Don’t touch it with alcohol material. This will destroy the sensor window.

4.  Configure LLDS12 via AT Command or LoRaWAN Downlink

Use can configure LLDS12 via AT Command or LoRaWAN Downlink.

 

There are two kinds of commands to configure LLDS12, they are:

  •  General Commands.

These commands are to configure:

  • General system settings like: uplink interval.

  • LoRaWAN protocol & radio related command.

They are same for all Dragino Device which support DLWS-005 LoRaWAN Stack. These commands can be found on the wiki: End Device AT Commands and Downlink Command

 

  •  Commands special design for LLDS12

These commands only valid for LLDS12, as below:

4.1  Set Transmit Interval Time

Feature: Change LoRaWAN End Node Transmit Interval.

AT Command: AT+TDC

image-20220607171554-8.png

Downlink Command: 0x01

Format: Command Code (0x01) followed by 3 bytes time value.

If the downlink payload=0100003C, it means set the END Node’s Transmit Interval to 0x00003C=60(S), while type code is 01.

  • Example 1: Downlink Payload: 0100001E // Set Transmit Interval (TDC) = 30 seconds

  • Example 2: Downlink Payload: 0100003C // Set Transmit Interval (TDC) = 60 seconds

     

4.2  Set Interrupt Mode

Feature, Set Interrupt mode for GPIO_EXIT.

AT Command: AT+INTMOD

image-20220610105806-2.png

Downlink Command: 0x06

Format: Command Code (0x06) followed by 3 bytes.

This means that the interrupt mode of the end node is set to 0x000003=3 (rising edge trigger), and the type code is 06.

  • Example 1: Downlink Payload: 06000000 // Turn off interrupt mode

  • Example 2: Downlink Payload: 06000003 // Set the interrupt mode to rising edge trigger

4.3  Get Firmware Version Info

Feature: use downlink to get firmware version.

Downlink Command: 0x26

image-20220607171917-10.png

  • Reply to the confirmation package: 26 01
  • Reply to non-confirmed packet: 26 00

Device will send an uplink after got this downlink command. With below payload:

Configures info payload:

Size(bytes)

1111151
ValueSoftware Type

Frequency

Band

Sub-band

Firmware

Version

Sensor TypeReserve

Message Type
Always 0x02

Software Type: Always 0x03 for LLDS12

Frequency Band:

*0x01: EU868

*0x02: US915

*0x03: IN865

*0x04: AU915

*0x05: KZ865

*0x06: RU864

*0x07: AS923

*0x08: AS923-1

*0x09: AS923-2

*0xa0: AS923-3

Sub-Band: value 0x00 ~ 0x08

Firmware Version: 0x0100, Means: v1.0.0 version

Sensor Type:

0x01: LSE01

0x02: LDDS75

0x03: LDDS20

0x04: LLMS01

0x05: LSPH01

0x06: LSNPK01

0x07: LLDS12

5.  Battery & How to replace

5.1  Battery Type

LLDS12 is equipped with a 8500mAH ER26500 Li-SOCI2 battery. The battery is un-rechargeable battery with low discharge rate targeting for 8~10 years use. This type of battery is commonly used in IoT target for long-term running, such as water meter.

The discharge curve is not linear so can’t simply use percentage to show the battery level. Below is the battery performance.

1654593587246-335.png

Minimum Working Voltage for the LLDS12:

LLDS12:  2.45v ~ 3.6v

5.2  Replace Battery

Any battery with range 2.45 ~ 3.6v can be a replacement. We recommend to use Li-SOCl2 Battery.

And make sure the positive and negative pins match.

5.3  Power Consumption Analyze

Dragino Battery powered product are all runs in Low Power mode. We have an update battery calculator which base on the measurement of the real device. User can use this calculator to check the battery life and calculate the battery life if want to use different transmit interval.

Instruction to use as below:

Step 1: Downlink the up-to-date DRAGINO_Battery_Life_Prediction_Table.xlsx from:

https://www.dragino.com/downloads/index.pHp?dir=LoRa_End_Node/Battery_Analyze/

Step 2: Open it and choose

  • Product Model
  • Uplink Interval
  • Working Mode

And the Life expectation in difference case will be shown on the right.

1654593605679-189.png

The battery related documents as below:

image-20220607172042-11.png

5.3.1  ​Battery Note

The Li-SICO battery is designed for small current / long period application. It is not good to use a high current, short period transmit method. The recommended minimum period for use of this battery is 5 minutes. If you use a shorter period time to transmit LoRa, then the battery life may be decreased.

​5.3.2  Replace the battery

You can change the battery in the LLDS12.The type of battery is not limited as long as the output is between 3v to 3.6v.  On the main board, there is a diode (D1) between the battery and the main circuit. If you need to use a battery with less than 3.3v, please remove the D1 and shortcut the two pads of it so there won’t be voltage drop between battery and main board.

The default battery pack of LLDS12 includes a ER26500 plus super capacitor. If user can’t find this pack locally, they can find ER26500 or equivalence, which will also work in most case. The SPC can enlarge the battery life for high frequency use (update period below 5 minutes)

6.  Use AT Command

6.1  Access AT Commands

LLDS12 supports AT Command set in the stock firmware. You can use a USB to TTL adapter to connect to LLDS12 for using AT command, as below.

1654593668970-604.png

Connection:

 USB TTL GND <----> GND

 USB TTL TXD  <----> UART_RXD

 USB TTL RXD  <----> UART_TXD

In the PC, you need to set the serial baud rate to 9600 to access the serial console for LSPH01. LSPH01 will output system info once power on as below:

 1654593712276-618.png

Valid AT Command please check Configure Device.

7.  FAQ

7.1  How to change the LoRa Frequency Bands/Region

You can follow the instructions for how to upgrade image.
When downloading the images, choose the required image file for download. ​

8.  Trouble Shooting

8.1  AT Commands input doesn’t work

In the case if user can see the console output but can’t type input to the device. Please check if you already include the ENTER while sending out the command. Some serial tool doesn’t send ENTER while press the send key, user need to add ENTER in their string. 

8.2  Significant error between the output distant value of LiDAR and actual distance

Cause ①Due to the physical principles of The LiDAR probe, the above phenomenon is likely to occur if the detection object is the material with high reflectivity (such as mirror, smooth floor tile, etc.) or transparent substance (such as glass and water, etc.)

Troubleshooting: Please avoid use of this product under such circumstance in practice.

 

Cause ②The IR-pass filters are blocked.

Troubleshooting: please use dry dust-free cloth to gently remove the foreign matter.

9.  Order Info

Part Number: LLDS12-XX

XX: The default frequency band

  • AS923:  LoRaWAN AS923 band
  • AU915: LoRaWAN AU915 band
  • EU433: LoRaWAN EU433 band
  • EU868: LoRaWAN EU868 band
  • KR920: LoRaWAN KR920 band
  • US915: LoRaWAN US915 band
  • IN865:  LoRaWAN IN865 band
  • CN470: LoRaWAN CN470 band

10. ​ Packing Info

Package Includes:

  • LLDS12 LoRaWAN LiDAR Distance Sensor x 1

Dimension and weight:

  • Device Size: cm
  • Device Weight: g
  • Package Size / pcs : cm
  • Weight / pcs : g

11.  ​Support

  • Support is provided Monday to Friday, from 09:00 to 18:00 GMT+8. Due to different timezones we cannot offer live support. However, your questions will be answered as soon as possible in the before-mentioned schedule.
  • Provide as much information as possible regarding your enquiry (product models, accurately describe your problem and steps to replicate it etc) and send a mail to support@dragino.com.

 

Tags:
Created by Xiaoling on 2022/06/22 16:39
    
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