EBYTE E220P-400T22S LoRa Wireless Module User Manual

June 6, 2024
ebyte

EBYTE E220P-400T22S LoRa Wireless Module

Overview

Introduction
E220P-400T22S is a new generation of LoRa wireless serial port module (UART), based on Semtech’s original LLCC68 chip design. It has a variety of transmission methods,The module has built-in PA+LNA, and the communication distance can reach 7km under ideal conditions. (E220P-400T22S is 5.6km) built- in LNA and ESD receiver, with stronger anti-interference ability and longer receiving distance. Using active crystal oscillator, frequency deviation ±1PPM, can normal communication under high temperature and low temperature conditions. works in the (410.125 ~ 493.125MHz) frequency band (default 433.125MHz), LoRa spread spectrum technology, TTL level output, compatible with 3.3V and 5V IO port voltage.

E220P-400T22S adopts a new generation of LoRa solution. Compared with the traditional SX1276 solution, the transmission distance is longer, the speed is faster, and the power consumption is lower; it supports functions such as air wake-up, carrier monitoring, and communication key, and supports sub-packet length setting. Ebyte can provide customized development services. Compared with the LLCC68 scheme, this scheme has a high cost performance advantage. The product can cover an ultra-wide frequency range of 410~493MHz.

Features

  • Using LLCC68 chip solution, it has significant advantages of low power consumption, fast speed and long distance;
  • Under ideal conditions, the communication distance can reach 5km;
  • The maximum transmit power is 22dBm, and the software is multi-level adjustable;
  • Support users to set the communication key by themselves, and it cannot be read, which greatly improves the confidentiality of user data;
  • Support RSSI signal strength indicator function for evaluating signal quality, improving communication network, and ranging;
  • Support air wakeup, that is, ultra-low power consumption function, suitable for battery-powered applications;
  • Support fixed-point transmission, broadcast transmission, channel monitoring;
  • Support the global ISM 433/470MHz frequency band;
  • The module has built-in PA+LNA, and the communication distance can reach 7km under ideal conditions. (E220-400 t22s 5.6 km)
  • Built-in LNA and ESD receiver, stronger anti-interference ability, longer receiving distance.
  • Using active crystal oscillator, frequency deviation ±1PPM, can normal communication under high temperature and low temperature conditions.
  • The parameters are saved after power off, and the module will work according to the set parameters after power on again;
  • Efficient watchdog design. Once an exception occurs, the module will automatically restart and continue to work according to the previous parameter settings;
  • Support the data transmission rate of 2.4k~62.5kbps;
  • Support 3.3~5.5V power supply, power supply greater than 5V can guarantee the best performance;
  • Industrial standard design, supporting long-term use at -40~+85℃;
  • Dual antennas are optional (IPEX/stamp hole), which is convenient for users to develop and integrate.

Application

  • Home security alarm and remote keyless entry;
  • Smart home and industrial sensors;
  • Wireless alarm security system;
  • Building automation solutions;
  • Wireless industrial-grade remote control;
  • Health care products;
  • Advanced Meter Reading Architecture(AMI);
  • Automotive industry applications.

Specifications and Parameters

Limit parameter

Main parameter

| Performance|

Remark

---|---|---
Min.| Max.

Power supply(V)

|

2.3

|

5.5

| Voltage over 5.5V will cause permanent damage to

module

Blocking power(dBm)

|

|

10

| Chances of burn is slim when modules are used in

short distance

Operating temperature(℃)| -40| +85| Industrial grade

Operating parameter

Main parameter

| Performance|

Remark

---|---|---
Min.| Typ.| Max.
Operating voltage(V)| 3.3| 5.0| 5.5| ≥5.0 V ensures output power
Communication level(V)| –| 3.3| –| For 5V TTL, it may be at risk of burning down
Operating temperature(℃)| -40| –| 85| Industrial design
Operating frequency(MHz)| 410.125| –| 493.125| Support ISM band
Power

consum ption

| TX current(mA)| –| 110| –| Instant power consumption @22dBm
RX current(mA)| –| 11| –| –
Sleep current (μA)| –| 2| –| Software is shut down
Max Tx power(dBm)| 21.5| 22.0| 22.5| –
Receiving sensitivity(dBm)| -132| -135| -136| Air speed 2.4 KBPS
Air data rate(bps)| 2.4k| 2.4k| 62.5k| Controlled via user’s programming

Distance for reference

|

7km

| Test condition:clear and open area, antenna gain: 5dBi,

antenna height: 2.5m,air data rate: 2.4kbps

TX length

|

200 Byte

| Can be configured via command as 32/64/128/200

bytes per packet to transmit

Buffer| 400 Byte| –
Modulation| LoRa| New generation LoRa modulation technology
Communication interface| UART| TTL Level
Package| SMD| –
Connector| 1.27mm| –
Size| 16*26 mm| –
---|---|---
Antenna| IPEX/stamp hole| 50 ohm impedance

Size and Pin Definition

EBYTE E220P-400T22S LoRa Wireless Module-fig3

No. Name Direction Features
1 GND Ground
2 GND Ground
3 GND Ground
4 GND Ground

5

| ****

M0

| Input

(weak pull-up)

| Work with M1 to decide 4 working modes of module (not suspended, if not

used, could be grounded).


6

| ****

M1

| Input

(weak pull-up)

| Work with M0 to decide 4 working modes of module (not suspended, if not

used, could be grounded).

7| RXD| Input| TTL UART inputs, connects to external (MCU, PC) TXD output pin.
8| TXD| Output| TTL UART outputs, connects to external RXD (MCU, PC) input pin.


9

| ****

AUX

| ****

Output

| Used to indicate the working status of the module;

The user wakes up the external MCU and outputs low level during power-on self- check initialization; (can be left floating)

10| VCC| –| Power supply: 2.3~ 5.5V DC
11| GND| –| Ground
---|---|---|---
12| NC| –| Empty Pin
13| GND| –| Ground
14| NC| –| Empty Pin
15| NC| –| Empty Pin
16| NC| –| Empty Pin
17| NC| –| Empty Pin
18| NC| –| Empty Pin
19| GND| –| Ground
20| GND| –| Ground
21| ANT| –| Antenna
22| GND| –| Ground

Connect to MCU

EBYTE E220P-400T22S LoRa Wireless Module-fig4

No.| Brief description of the connection between the module and the MCU (The picture above takes STM8L MCU as an example)
---|---
1| The wireless serial port module is TTL level, please connect with TTL level MCU.
2| For some MCU works at 5VDC, it may need to add 4-10K pull-up resistor for the TXD & AUX pin.

Function Description

Fixed Transmission

EBYTE E220P-400T22S LoRa Wireless Module-fig5

Broadcasting Transmission

EBYTE E220P-400T22S LoRa Wireless Module-fig6

Broadcasting address

  • For example: Set the address of module A as 0xFFFF or 0x0000, and the channel as 0x04;
  • When module is the transmitter (transparent transmission), all modules under channel 0x04 will receive the data, the purpose of broadcast is realized.

Monitor address

  • For example: Set the address of module A as 0xFFFF or 0x0000, and the channel as 0x04;
  • When module A is the receiver, it can receive the data sent from all modules under channel 0x04, the purpose of monitor is realized.

Reset

When the module is powered, AUX outputs low level immediately, conducts hardware self-check and sets the operating mode based on user’s parameters. During the process, the AUX remains low level. After the process completed, the AUX outputs high level and starts to work as per the operating mode combined by M1 and M0. Therefore, users need to wait the AUX rising edge as the start of module’s normal work.

AUX description

  • AUX Pin can be used as indication for wireless send & receive buffer and self-check.
  • It can indicate whether there are data that are not sent yet via wireless way, or whether all wireless data has been sent through UART, or whether the module is still in the process of self-check initialization.

Indication of UART output
To wake up the external MCU

EBYTE E220P-400T22S LoRa Wireless Module-fig7

Indication of wireless transmitting

Buffer empty: the data in the internal 400-byte buffer is written to the wireless chip (automatic sub-packaging); When AUX=1, the user continuously initiates data less than 400 bytes without overflow;

When AUX=0, the buffer is not empty: the data in the internal 400-byte buffer has not been written to the wireless chip and the transmission is started. At this time, the module may be waiting for the end of the user data to time out, or the wireless sub-packet transmission is in progress.
[Note]: When AUX=1, it does not mean that all serial port data of the module has been transmitted wirelessly, and the last packet of data may be being transmitted.

EBYTE E220P-400T22S LoRa Wireless Module-fig8

Notes for AUX

No. AUX Description

1

| For function 1 & function 2 mentioned above, the priority should be given to the one with low level output, which means if it meets each of any low level output condition, AUX outputs low level, if none of the low level condition is met, AUX

outputs high level.

2| When AUX outputs low level, it means the module is busy & cannot conduct operating mode checking. Within 1ms since AUX outputs high level, the mode switch will be completed.
3| After switching to new operating mode, it will not work in the new mode immediately until AUX rising edge lasts for 2ms. If AUX stays on the high level, the operating mode switch can be affected immediately.
4| When the user switches to other operating modes from mode 3 (sleep mode) or it’s still in reset process, the module will reset user parameters, during which AUX outputs low level.

5

| Due to the characteristics of the LoRa modulation method, the information transmission delay is much longer than that of FSK. For example, at 2.4kbps airspeed, the 100-byte transmission delay is about 1.5 seconds. It is recommended that customers do not transmit large amounts of data at low airspeeds. , So as to avoid communication abnormalities caused by

data loss due to data accumulation.

Operating Mode

There are four operating modes, which are set by M1 and M0, the details are as follows:

Mode 0-3 M1 M0 Description Remark
0 Transmission Mode 0 0 UART and wireless channel are open, transparent
transmission is on

1 WOR

Transmitting Mode

|

0

|

1

|

WOR transmits data, WOR receives data

|

Supports wake up over air

2 WOR

Receiving Mode

| 1| 0| WOR transmitting is closed, WOR receiving data| —
3 Deep Sleep Mode| 1| 1| Parameters can be configured| —

Mode Switching

No. Remark

1

| l   Users can combine M1 and M0 with high and low levels to determine the operating mode. Two GPIOs of the MCU can be used to control mode switching;

l   After changing M1 and M0: If the module is idle, after 1ms, it can start working according to the new mode;

l   If the serial port data of the module has not been transmitted through the wireless, the new working mode can be switched after the transmission is completed;

l   If the module receives the wireless data and transmits the data through the serial port, it needs to finish transmission before switching the new working mode;

l   Therefore, mode switching can only be valid when AUX output is 1, otherwise it will delay switching

2

| l   For example, users continuously input a large amount of data and simultaneously performs mode switching. At this  time, the switching mode operation is invalid; the module will process all the user data before performing the new mode detection;

l   Therefore, the general recommendation is to detect the output state of the AUX pin and switch after 2ms when the output is high.

3

| l   When the module is switched from other modes to sleep mode, if the data has not been processed yet;

l   The module will process these data (including receiving and sending) before entering sleep mode. This feature can be used for fast sleep, which saves power; for example, the transmitter module works in mode 0, the user transmits the serial port data “12345”, and then does not have to wait for the AUX pin to be idle (high level), and can directly switch to sleep mode. And the user’s main MCU immediately sleeps, the module will automatically transmit the user data through the wireless, and automatically enters sleep within 1ms;

l   This saves MCU’s working time and reduces power consumption.

4

|

l   Similarly, any mode switching can use this feature. After the module processes the current mode event, it will automatically enter the new mode within 1ms; thus, eliminating the need for the user to query AUX and achieve the purpose of fast switching;

l   For example, switching from the transmit mode to the receive mode; the user MCU can also enter sleep before the mode switch, and use the external interrupt function to acquire the AUX change, thereby performing mode switching.

5

|

l   This operation mode is very flexible and efficient, and is designed according to the user’s MCU’s operation convenience, and can reduce the workload of the entire system as much as possible, improve system efficiency, and reduce power consumption.

Normal mode(Mode 0)

Type

|

When M0 = 0, M1 = 0, the module works in mode 0

---|---

Transmitting

|

Users can input data through the serial port and the module will start wireless transmission.

Receiving

| The module wireless receiving function is turned on, and after receiving the wireless data, it will be output through the serial port TXD pin.

WOR sending mode (Mode 1)

Type

|

When M0 = 1, M1 = 1, the module works in mode 1

---|---

Transmitting

|

Wireless data transmitting is turned on.

Receiving

|

Wireless data reception is turned on.

WOR receiving mode (Mode 2)

Type

|

When M0 = 0, M1 = 1, the module works in mode 2

---|---

Transmitting

|

Wireless transmission is off.

Receiving

|

Wireless data reception is turned on.

Deep Sleep Mode (Mode 3)

Type When M0 = 1, M1 = 1, the module works in mode 3

Transmitting

|

Unable to transmit wireless data

Receiving

|

Unable to receive wireless data

Configurating

|

Users can access the registers to configure the working status of the module

Note

| When from the sleep mode to other modes, the module will reconfigure the parameters. During the configuration process, AUX will remain low; After configuration, it outputs high level, we suggest that user test rising edge T_BUSY.

Register Read and Write Control

Command Format

In configuration mode (mode 3: M1=1, M0=1), the supported command list is as follows (when setting, only 9600, 8N1 format is supported):

No Command Format Description

1

|

Set Register

| Command: C0+starting address+length+parameters Response: C1+starting address+length+parameters

Example 1: Channel is 0x09

command      starting address length parameter Send: C0 05                  01          09

Return: C1                    05                  01          09

Example 2:Configure module address (0x1234), serial port (9600 8N1), air speed (2.4K) Send:C0 00 04 12 34 00 61

Return:C1 00 04 12 34 00 61

2

|

Read Register

| Command: C1+starting address+parameters Response: C1+starting address+length+parameters

Example:Read channel

command starting address length parameter Send: C1                    05 01

Return: C1                  05                  01          09

Example 2: Read module address, serial port, and airspeed at the same time Send:C1 00 04

Return:C1 00 04 12 34 00 61

3

|

Set Temporary Register

| Command: C2+starting address+parameters Response: C1+starting address+length+parameters

Example 1: Channel is 0x09

command starting address length parameter Send:   C2                  05 01          09

Return: C1                  05                  01          09

Example 2: Configure module address (0x1234), network address (0x00), serial port (9600 8N1) and air data rate (2.4K)

Send:C2 00 04 12 34 00 61

Return:C1 00 04 12 34 00 61

4

|

Wrong Format

| Wrong format responds FF FF FF

Register Description

Address

| Read or

Write

|

Name

|

Description

|

Remark

---|---|---|---|---

00H

| Read/ Write|

ADDH

|

ADDH(default 0)

| High byte and low byte of module address;

Note: When the module address is equal to FFFF,

01H

|

Read/ Write

|

ADDL

|

ADDL(default 0)

| it can be used as the broadcast and monitor

address, that is: the module will not perform address filtering at this time

|
---|---|---|---|---|---
| | | 7| 6| 5| UART Serial Port Rate(bps)|

For the two modules that communicate with each other, the serial port baud rate can be different, and the verification method can also be different;

When continuously transmitting large data packets, users need to consider the data congestion caused by the same baud rate, and may even be lost;

It is generally recommended that the baud rate of the two communication parties be the same.

|
| | | 0| 0| 0| UART Rate is 1200|
| | | 0| 0| 1| UART Rate is 2400|
| | | 0| 1| 0| UART Rate is 4800|
| | | 0| 1| 1| UART Rate is 9600(default)|
| | | 1| 0| 0| UART Rate is 19200|
| | | 1| 0| 1| UART Rate is 38400|
| | | 1| 1| 0| UART Rate is 57600|
| | | 1| 1| 1| UART Rate is 115200|
| | | 4| 3| Serial Parity Bit| |

02H

|

Read/ Write

|

REG0

| 0| 0| 8N1(default)|

The serial port mode of the communication parties can be different;

|
0| 1| 8O1|
1| 0| 8E1|
| | | 1| 1| 8N1(equal to 00)| |
| | | 2| 1| 0| Air Data Rate(bps)|

The air rate of both parties must be the same; The higher the air rate, the smaller the delay and the shorter the transmission distance.

|
| | | 0| 0| 0| Air Data Rate 2.4k|
| | | 0| 0| 1| Air Data Rate 2.4k|
| | | 0| 1| 0| Air Data Rate 2.4k(default)|
| | | 0| 1| 1| Air Data Rate 4.8k|
| | | 1| 0| 0| Air Data Rate 9.6k|
| | | 1| 0| 1| Air Data Rate 19.2k|
| | | 1| 1| 0| Air Data Rate 38.4k|
| | | 1| 1| 1| Air Data Rate 62.5k|
| | | 7| 6| Sub-Packet Setting| The data sent by the user is less than the

sub-packet length, and the serial port output of the receiving end appears as an uninterrupted continuous output;

The data sent by the user is larger than the packet length, and the serial port of the receiving end will be output in packets.

|
| | | 0| 0| 200 bytes(default)|
| | | 0| 1| 128 bytes|
| | | 1| 0| 64 bytes|
| | |

1

|

1

|

32 bytes

|
| | | 5| RSSI Ambient noise enable| After enabling, you can send commands C0 C1|
| | | C2 C3 in transmission mode or WOR sending|
0| Disable(Default)|

03H

| Read/ Write|

REG1

| mode to read registers;

Register 0x00: Current environmental noise RSSI; Register 0X01: RSSI when receiving data last

time

|
| |
| | | | | (The current channel noise is: dBm = – ( 256 –|
| | | | | RSSI));|
| | | 1| Enable| Instruction     format:     C0     C1     C2 C3+start|
| | | | | address+read length;|
| | | | | Return: C1 + address + read length + read valid|
| | | | | value; for example: send C0 C1 C2 C3 00 01|
| | | | | Return C1 00 01 RSSI (address can only start|
| | | | | from 00)|
| | | 4| 3| 2| Reserve| |
| | | |
| | | 1| 0| Transmitting Power| The relationship between power and current is non-linear, and the power supply has the highest efficiency at maximum power;

The current will not decrease in the same proportion as the power decreases.

---|---|---|---|---|---|---
0| 0| 22dBm(default)
0| 1| 17dBm
1| 0| 13dBm
1| 1| 10dBm

04H

| Read/

Write

|

REG2

| Channel Control(CH)

0-83 represents a total of 84 channels

|

Actual frequency = 410.125 + CH *1M

05H

|

Read/ Write

|

REG3

| 7| Enable RSSI Byte| After being enabled, the module receives wireless data and outputs it through the serial port TXD, followed by an RSSI strength byte.
0| Disable(Default)
1| Enable
6| Transmission Method| During fixed transmission, the module will recognize the first three bytes of serial data as: address high + address low + channel, and use it as a wireless transmission target.
0| Transparent transmission mode(default)
1| Fixed transmission mode
5| Reserve|
4| LBT Enable| After enabling, monitoring will be conducted before wireless data transmission, which can avoid interference to a certain extent, but may cause data delay;

The maximum stay time of LBT is 2 seconds, and it will be issued forcibly when it reaches 2 seconds.

0| Disable(default)

1

|

Enable

3| Reserve|
2| 1| 0| WOR Cycle|

Only valid for mode 1;

Cycle T= (1+WOR)*500ms, the maximum is 4000ms, the minimum is 500ms;

The longer the WOR monitoring interval period, the lower the average power consumption, but the greater the data delay;

Both sender and receiver must agree (very important)

0| 0| 0| 500ms
0| 0| 1| 1000ms
0| 1| 0| 1500ms
0| 1| 1| 2000ms
1| 0| 0| 2500ms
1| 0| 1| 3000ms
1| 1| 0| 3500ms
1| 1| 1| 4000ms

06H

|

Write

| CRYPT

_H

| Key high byte(default 0)| Write only, read returns 0;

Used for encryption to avoid interception of wireless data in the air by similar modules;

The module will use these two bytes as a calculation factor to transform and encrypt the air

wireless signal.

07H

|

Write

|

CRYPT

_L

|

Key low byte(default 0)

Factory Default Parameter

Model Factory default parameter C0 00 00 62 00 17

Model No.

|

Frequency

|

Address

|

Channel

|

Air Rate

|

Baud Rate

|

Serial Format

|

Power

E220P-400T22S

|

433.125MHz

|

0x0000

|

0x17

|

2.4kbps

|

9600

|

8N1

|

22dbm

Configuration Instruction on Computer

  • The following figure shows the display interface of the E220P-400T22S configuration host computer. The user can switch to the command mode through M0 and M1, and quickly configure and read the parameters on the host computer.EBYTE E220P-400T22S LoRa Wireless Module-fig10
  • In the configuration of the host computer, the module address, frequency channel, network ID, and key are all displayed in decimal mode; the value range of each parameter:
    • Network address:0~65535
    • Frequency channel:0~83
    • Internet ID:0~255
    • Key:0~65535

Hardware Design

  • It is recommended to use a DC stabilized power supply to supply power to the module. The power ripple coefficient should be as small as possible, and the module must be reliably grounded;
  • Please pay attention to the correct connection of the positive and negative poles of the power supply. Reverse connection may cause permanent damage to the module;
  • Please check the power supply to ensure that it is within the recommended power supply voltage. If it exceeds the maximum value, it will cause permanent damage to the module;
  • Please check the stability of the power supply, the voltage should not fluctuate greatly and frequently;
  • When designing the power supply circuit for the module, it is often recommended to reserve more than 30% of the margin, and the whole machine is conducive to long-term stable operation;
  • The module should be as far away as possible from power supply, transformer, high frequency wiring and other parts with large electromagnetic interference;
  • High-frequency digital traces, high-frequency analog traces, and power traces must avoid under the module. If they really need to pass under the module, assuming that the module is soldered to the Top Layer, lay copper on the Top Layer of the contact part of the module (all copper and Good grounding), must be close to the digital part of the module and routed in the Bottom Layer;
  • Assuming that the module is soldered or placed on the Top Layer, it is also wrong to randomly route the wires on the Bottom Layer or other layers, which will affect the stray and receiving sensitivity of the module to varying degrees;
  • Assuming that there are devices with large electromagnetic interference around the module, it will greatly affect the performance of the module. According to the intensity of the interference, it is recommended to stay away from the module. If the situation permits, proper isolation and shielding can be done;
  • Assuming that there are traces with large electromagnetic interference around the module (high-frequency digital, high-frequency analog, power wiring), it will also greatly affect the performance of the module. According to the intensity of the interference, it is recommended to stay away from the module. Isolation and shielding;
  • Try to stay away from part of the physical layer that is also 2.4GHz TTL protocol, such as: USB3.0;
  • The antenna installation structure has a great influence on the performance of the module. Make sure that the antenna is exposed and it is best to be vertically upward;
  • When the module is installed inside the case, a high-quality antenna extension cable can be used to extend the antenna to the outside of the case;
  • The antenna must not be installed inside the metal shell, which will greatly reduce the transmission distance.

FAQ

Communication range is too short

  • When there is a straight-line communication obstacle, the communication distance will be attenuated accordingly;
  • Temperature, humidity, and co-frequency interference will increase the communication packet loss rate;
  • The ground absorbs and reflects radio waves, and the test results near the ground are poor;
  • Sea water has a strong ability to absorb radio waves, so the seaside test results are poor;
  • If there is a metal object near the antenna or placed in a metal shell, the signal attenuation will be very serious;
  • The power register setting is wrong, the air speed setting is too high (the higher the air speed, the closer the distance);
  • The low voltage of the power supply at room temperature is lower than the recommended value, the lower the voltage, the lower the power output;
  • The matching degree of the antenna and the module is poor or the quality of the antenna itself is problematic.

Module is easy to damage

  • Please check the power supply to ensure that it is within the recommended power supply voltage. If it exceeds the maximum value, the module will be permanently damaged;
  • Please check the stability of the power supply, and the voltage should not fluctuate greatly and frequently;
  • Please ensure anti-static operation during installation and use, and high-frequency components are electrostatically sensitive;
  • Please ensure that the humidity during installation and use should not be too high, and some components are humidity sensitive devices;
  • If there is no special requirement, it is not recommended to use it at too high or too low temperature.

BER (Bit Error Rate) is high

  • There is co-frequency signal interference nearby, stay away from the interference source or modify the frequency and channel to avoid interference;
  • Unsatisfactory power supply may also cause garbled codes. Ensure the reliability of the power supply;
  • Poor or too long extension cables and feeders can also cause high bit error rates.

Soldering Operation Guidance

Reflow Soldering Temperature

Profile Feature Sn-Pb Assembly Pb-Free Assembly
Solder Paste Sn63/Pb37 Sn96.5/Ag3/Cu0.5
Preheat Temperature min (Tsmin) 100℃ 150℃
Preheat temperature max (Tsmax) 150℃ 200℃
Preheat Time (Tsmin to Tsmax)(ts) 60-120 sec 60-120 sec
Average ramp-up rate(Tsmax to Tp) 3℃/second max 3℃/second max
Liquidous Temperature (TL) 183℃ 217℃
Time(tL)Maintained Above(TL) 60-90 sec 30-90 sec
Peak temperature(Tp) 220-235℃ 230-250℃
Aveage ramp-down rate(Tp to Tsmax) 6℃/second max 6℃/second max
Time 25℃ to peak temperature 6 minutes max 8 minutes max

Reflow Soldering Curve

EBYTE E220P-400T22S LoRa Wireless Module-fig11

Related Models


Model No.

| ****

Chip Scheme

| Frequency

Hz

| Tx power

dBm

| Distance

km

| ****

Package

| ****

Interface

---|---|---|---|---|---|---
E220-400T30S| LLCC68| 433/470M| 30| 10| SMD| TTL

Antenna Recommendation

Antennas are an important role in the communication process, and often inferior antennas will have a great impact on the communication system. Therefore, our company recommends some antennas as supporting our company’s wireless modules with excellent performance and reasonable prices.

Model No.| Type| Frequency| Interface| Gain| Height| Feeder| Features
---|---|---|---|---|---|---|---
| | Hz| | dBi| mm| cm|
---|---|---|---|---|---|---|---

TX433-JZ-5

|

Rubber Antenna

|

433M

|

SMA-J

|

2.0

|

52

|

| Ultra-short straight,

omnidirectional antenna

TX433-JZG-6

|

Rubber Antenna

|

433M

|

SMA-J

|

2.5

|

62

|

| Sort straight, omnidirectional

antenna

TX433-JW-5

|

Rubber Antenna

|

433M

|

SMA-J

|

2.0

|

50

|

| Ultra-short straight,

omnidirectional antenna

TX433-JWG-7

|

Rubber Antenna

|

433M

|

SMA-J

|

2.5

|

75

|

| Bend rubber, omnidirectional

antenna

TX433-JK-11

|

Rubber Antenna

|

433M

| SMA-J|

2.5

|

110

|

| Bendable rubber,

omnidirectional antenna

TX433-JK-20

|

Rubber Antenna

|

433M

| SMA-J|

3.0

|

210

|

| Bendable rubber,

omnidirectional antenna

TX433-XPL-100

|

Suction Antenna

|

433M

|

SMA-J

|

3.5

|

185

|

100

| Small suction antenna,

cost-effective

TX433-XP-200

|

Suction Antenna

|

433M

|

SMA-J

|

4.0

|

190

|

200

| Middle suction antenna, high

gain

TX433-XPH-300| Suction Antenna| 433M| SMA-J| 6.0| 965| 300| Big suction antenna, high gain

TX490-JZ-5

|

Rubber Antenna

|

470/490M

|

SMA-J

|

2.0

|

50

|

| Ultra-short straight,

omnidirectional antenna

TX490-XPL-100

|

Suction Antenna

|

470/490M

|

SMA-J

|

3.5

|

120

|

100

| Small suction antenna,

cost-effective

Package for Bulk Order

EBYTE E220P-400T22S LoRa Wireless Module-fig12

Revision History

Version Date Description Issued by
1.0 2021-9-24 Original Version Linson

About us
Technical support: support@cdebyte.com
Documents and RF Setting download link: www.ebyte.com
Thank you for using Ebyte products! Please contact us with any questions or suggestions: info@cdebyte.com

Official hotline:028-61399028
Web:www.ebyte.com
Address: , Building B5, Mould Industrial Park, 199# Xiqu Ave, High-tech Zone, Chengdu, 611731, Sichuan, China

References

Read User Manual Online (PDF format)

Read User Manual Online (PDF format)  >>

Download This Manual (PDF format)

Download this manual  >>

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