LBEE5XV1YM Wi-Fi Plus Bluetooth Module
Instruction Manual
LBEE5XV1YM Wi-Fi Plus Bluetooth Module Instruction Manual
NXP 88W8997 Chipset for 802.11a/b/g/n/ac 2×2 MIMO + Bluetooth 5.2
Hardware Application Note – Rev. 6.0
- Design Name: Type 1YM
- P/N: LBEE5XV1YM-574
About This Document
Murata’s Type 1YM is a small and high-performance module based on NXP 88W8997 combo chipset, supporting IEEE 802.11a/b/g/n/ac 2×2 MIMO + Bluetooth 5.2 BR/EDR/LE. This application note provides RF and hardware design guidance. Refer to Type 1YM Datasheet for module specification.
Audience & Purpose
Intended audience includes any customer looking to integrate this module into their product. In particular, RF, hardware, systems, and software engineers.
Document Conventions
Table 1 describes the document conventions.
Table 1: Document Conventions
| Conventions | Description |
|
|
Warning Note Indicates very important note. Users are strongly recommended to review. |
|
|
Info Note Intended for informational purposes. Users should review. |
|
|
Menu Reference Indicates menu navigation instructions. Example: Insert Tables Quick Tables Save Selection to Gallery  |
|
|
External Hyperlink This symbol indicates a hyperlink to an external document or website. Example: Murata  Click on the text to open the external link. |
|
|
Internal Hyperlink This symbol indicates a hyperlink within the document. Example: Scope  Click on the text to open the link. |
| Console input/output or code snippet | Console I/O or Code Snippet This text Style denotes console input/output or a code snippet. |
| # Console I/O comment // Code snippet comment | Console I/O or Code Snippet Comment This text Style denotes a console input/output or code snippet comment. · Console I/O comment (preceded by “#”) is for informational purposes only and does not denote actual console input/output. · Code Snippet comment (preceded by “//”) may exist in the original code. |
Scope
This application note provides detailed information on schematic/layout design, and references RF performance benchmarks. Refer to for Type 1YM Datasheet for module specification.
Module Introduction
Type 1YM is a high-performance module based on NXP 88W8997 combo chipset, which supports Wi-Fi 802.11a/b/g/n/ac 2×2 MIMO + Bluetooth 5.2 BR/EDR/LE up to 866 Mbps PHY data rate on Wi-Fi and 3 Mbps PHY data rate on Bluetooth.
The 88W8997 implements highly sophisticated enhanced collaborative coexistence hardware mechanisms and algorithms, which ensure that WLAN and Bluetooth collaboration is optimized for maximum performance.
2.1 Features
- WLAN 802.11a/b/g/n/ac 2×2 MIMO + Bluetooth Classic and Low Energy (Version 5.2) combo SMD module with NXP 88W8997
- Small size LGA package with resin molding and metal shielding.
- Host interfaces: PCIe 3.0, SDIO 3.0, and USB 2.0/3.0 for WLAN; and HCI UART, SDIO 3.0, USB 2.0/3.0, and PCM for Bluetooth.
- MAC address and BD address are stored in OTP.
WLAN-USB, Bluetooth-SDIO, and Bluetooth-USB interfaces may not be supported in software.
Refer to Type 1YM webpage or check 1YM Community Forum page .
2.2 Hardware Block Diagram
Figure 1 shows the block diagram of Type 1YM module. “ANT_B” is shared between WLAN and Bluetooth, “ANT_A” is dedicated to WLAN.
Reference Design
This section describes the reference design for Type 1YM.
3.1 Reference Circuitry
Figure 2 shows the u.FL/MHF I connector reference design for Type 1YM module.
When interfacing WLAN-PCIE, DC blocker 0.1 µF capacitors on both PCIe RXP and RXN signals should be located very close to the transmission point – i.e. close to the host processor PCIe transmit lines.
Although multiple variations of WLAN/Bluetooth host interface configurations are shown, WLAN-USB, Bluetooth-SDIO, and Bluetooth-USB interfaces may not be supported in software. Refer to Type 1YM webpage or check 1YM Community Forum page .
Figure 2: u.FL/MHF I Connector
3.2 Requirements for High-Speed Digital Signals
- SDIO: SDIO traces should be isometric zero delay routing with 50 Ω impedance.
- PCIe: TxP/N, RxP/N and CLKP/N signals should be differential 100 Ω impedance. DC blockers are necessary on RxP/N (these should be located very close to the transmission point, i.e., close to the host processor PCIe transmit lines).
- USB: DP/DM should be differential 90 Ω impedance.
3.3 Requirements for Unused Signals
No pull-up/down is necessary (floating) for GPIO [0..20] if these signals are not used.
3.4 Module Footprint Design
Refer to dimensions in the Type 1YM Datasheet of module footprint “type1ym_module_footprint_topview.dxf” is provided on the website.
3.5 Recommended Antenna
This module is certified with an antenna solution by regulatory certification body. To use Murata’s regulatory certification, any user must follow the instructions below. The DXF File “Type1YM_u.FL.dxf” is provided via web site.
3.5.1 PCB Type Di-pole Antenna with the Co-axial Connector
- Users must use recommended antennas. The approved vendor and its parameters for Dipole antenna is shown in Table 2. However, an antenna of equivalent type that has less antenna gain than antenna gain of recommended antennas for US/CA and EU can be used.
However, it must be as per Class I Permissive Change approved by Murata. An example of a Class I Permissive Change capable antenna is shown in Table 3. - JP is required to add an antenna in the Certified antenna list if user use an antenna that is not in the certified antenna list in Table 2 and Table 4.
Table 2: Recommended Antennas
| P/N | Vendor | Form Factor | Type | 2.4 GHz Gain | 5 GHz Gain | Cable Options |
| 146153 | Molex | u.FL/PCB | Dipole | 3.2 dBi | 4.25 dBi | 050,100,150,200,250 and 300 |
| 146187 | Molex | u.FL/PCB | Dipole | 3.0 dBi | 4.25 dBi | 050,100,150,200,250 and 300 |
Table 3: An Example of Class I Permissive Change Capable Antenna
| P/N | Vendor | Form factor | Type | 2.4 GHz Gain | 5 GHz Gain | Cable options |
| WT32D1-KX | Unictron | MHF I/PCB | Dipole | 3.0 dBi | 4.0 dBi | 119 mm (H2B1WD1A3B0200) |
If using an antenna vendor that is not listed (Antenova, Pulse, Taoglas, TE, etc.) with the Class I Permissive Change, please evaluate the antenna complies with the technical rules of the FCC KDB 178919 Permissive Change Policy
Table 4: Additional Registered Antennas in Japan Radio Law certification
| P/N | Vendor | Form factor | Type | 2.4 GHz Gain | 5 GHz Gain | Cable Options |
| 206994 | Molex | u.FL/PCB | Monopole | 3.6 | 3.6 | 100 mm or more |
| 219611 | Molex | u.FL/PCB | Dipole | 2.67 | 3.67 | 40 mm or more |
| WT32D1-KX | Unictron | MHF I/PCB | Dipole | 3.0 | 4.0 | 119 mm or more |
| AA258 | Unictron | MHF I/PCB | Dipole | 0.9 | 3.8 | 100 mm or more |
| TA-38B-A-W01 | Unictron | RSMA | Dipole | 2.61 | 3.07 | |
| TA-6B-A-WE01 | Unictron | RSMA | Dipole | 2.23 | 4.59 | |
| FXP830.07.0100C | Taoglas | MHF I/PCB | Dipole | 2.5 | 4.7 | 100 mm |
| GW.48.A151 | Taoglas | RSMA | Dipole | 1.82 | 3.28 | |
| GW.40.2153 | Taoglas | RSMA | Dipole | 3.15 | 4.39 | |
| GW.52.A153 | Taoglas | RSMA | Dipole | 2.93 | 4.53 | |
| SRF2W012 | Antenova | MHF I/PCB | Dipole | 3.0 | 4.0 | 100 mm or more |
| STDANTEMD-013 | Sansei | MHF I/PCB | Dipole | 1.9 | 2.8 | 120 mm |
| EMF2471A3S | Laird | MHF I/PCB | Dipole | 2.4 | 4.4 | 100 mm |
| 1001932FT | KAVX | MHF I/PCB | Dipole | 2.5 | 4.4 | 100 mm or more |
| 1001932PT | KAVX | MHF I/PCB | Dipole | 2.03 | 4.45 | 100 mm or more |
| W24P-U | Inventek | u.FL/PCB | Dipole | 3.2 | – | 90 mm |
Users must copy RF trace to u.FL/MHF I connector from the trace layout file provided by Murata in adherence to the guidelines on:
- Trace width accuracy within +/- 0.25 mm.
- Stack height between GND layer and RF trace of 230 ~ 240 µm (Exclude inaccuracy of PCB).
- Passive component location matching Murata design.
- Necessary “Keep out” area around u.FL/MHF I connector.
Figure 3 shows the Murata reference RF trace to u.FL/MHF I connector.
Figure 3: Murata Reference RF Trace to u.FL/MHF I Connector
3.5.2 PCB Stack-Up
Figure 4 shows the PCB stack-up design.
Figure 4: PCB Stack-Up
Setup Configuration Files
To enable Murata’s regulatory certification, the configuration stated below file should be initially loaded. Murata will provide configuration files through Murata GitHub Link (XX is the country code). For more regulatory information, refer to section 11 of Linux User Guide .
4.1 WLAN Configuration Files for Linux
The files listed in Table 5 should be used to meet the regulatory requirements if user wants to use Murata regulatory certification.
Table 5: WLAN Configuration Files – Linux
| Names | Country | Country Code | Configuration Files |
| WLAN Tx power configuration files | USA | US | txpower_US.bin |
| Canada | CA | txpower_CA.bin | |
| Europe | DE | txpower_EU.bin | |
| Japan | JP | txpower_JP.bin | |
| WLAN Carrier Sense / Adaptivity threshold configuration file | ed_mac.bin | ||
| WLAN regulatory limitation configuration file | db.txt |
NXP IC based module must use CRDA mechanism which is provided by Linux-wireless. Compile the new regulatory.bin file from “db.txt” that is provided by Murata with following manner of wireless- regdb .
4.2 Bluetooth Configuration Files for Linux
Bluetooth Tx power configuration script file should be loaded after Bluetooth device initialization.
- Bluetooth Tx power configuration files
- bt_power_config_1.sh
- Command example:
# sh bt_power_config_1.sh - Content of shell script file “bt_power_config_1.sh”
hcitool -i hci0 cmd 0x3f 0x00ee 0x01
Bluetooth Tx power is configured by using hcitool.
Reference Performance Data
This section describes the reference performance data for WLAN and Bluetooth with respect to different countries.
5.1 Typical Rx Minimum Sensitivity Level at Module Antenna Port
This section describes the Typical Rx Minimum Sensitivity Level at module antenna port is for WLAN and Bluetooth.
5.1.1 WLAN
Conditions:
- VBAT = 3.3V, VIO = 1.8V
- Combo FW: 16.80.205p146
Table 6 describes the typical Rx minimum sensitivity level for Wi-Fi at 2.4 GHz.
Table 6: Typical Rx Minimum Sensitivity Level for Wi-Fi – 2.4 GHz
| Frequency in MHz | Rx Minimum Sensitivity Level in dBm | |||||
| 11b | 11g | 11n | ||||
| 1 Mbps | 11 Mbps | 6 Mbps | 54 Mbps | MCS0 | MCS7 | |
| 2412 | -98 | -89 | -89 | -75 | -89 | -74 |
| 2442 | -98 | -89 | -89 | -75 | -89 | -74 |
| 2472 | -98 | -89 | -88 | -75 | -88 | -73 |
Table 7, Table 8, and Table 9 describes the typical Rx minimum sensitivity level for 5 GHz Wi-Fi at 20 MHz, 40 MHz and 80 MHz bandwidth.
Table 7: Typical Rx Minimum Sensitivity Level for Wi-Fi – 5 GHz (HT/VHT 20
| Frequency in MHz | Rx Minimum Sensitivity Level in dBm | |||||
| 11a | 11n (HT20) | 11ac (VHT20) | ||||
| 6 Mbps | 54 Mbps | MCS0 | MCS7 | MCS0 | MCS8 | |
| 5180 | -87 | -72 | -87 | -70 | -87 | -67 |
| 5500 | -87 | -72 | -87 | -70 | -87 | -67 |
| 5825 | -87 | -72 | -87 | -70 | -87 | -67 |
Table 8: Typical Rx Minimum Sensitivity Level for Wi-Fi – 5 GHz (VHT 40)
| Frequency in MHz | Rx Minimum Sensitivity Level in dBm | |
| 11ac (VHT40) | ||
| MCS0 | MCS9 | |
| 5190 | -83 | -64 |
| 5510 | -83 | -64 |
| 5795 | -84 | -64 |
Table 9: Typical Rx Minimum Sensitivity Level for Wi-Fi – 5 GHz (VHT 80)
| Frequency in MHz | Rx Minimum Sensitivity Level in dBm | |
| 11ac (VHT80) | ||
| MCS0 | MCS9 | |
| 5180 | -79 | -60 |
| 5500 | -79 | -60 |
| 5825 | -79 | -60 |
5.1.2 Bluetooth
Conditions:
- VBAT = 3.3V, VDDIO = 1.8V
- Combo FW: 16.80.205p146
Table 10 describes the typical Rx minimum sensitivity level for Bluetooth.
Table 10: Typical Rx Minimum Sensitivity Level – Bluetooth
| Frequency in MHz | Rx Minimum Sensitivity Level in dBm | ||||
| DH5 | 2DH5 | 3DH5 | LE 1M | LE 2M | |
| 2412 | -94 | -92 | -89 | -100 | -98 |
| 2442 | -95 | -94 | -89 | -100 | -95 |
| 2472 | -94 | -92 | -89 | -97 | -93 |
5.2 Typical Tx/Rx Current Consumption
This section describes the Typical Tx/Rx current consumption for WLAN and Bluetooth.
5.2.1 WLAN
Conditions:
- Host IF: PCIe
- VBAT = 3.3V, VIO = 1.8V
- Combo FW: 16.80.205p146
- Current definition
Figure 5: Typical Tx/Rx Current Consumption – WLAN
Table 11 and Table 12 describe the typical Tx/Rx current consumption in WLAN PCIe mode for 2.4 GHz and 5 GHz.
Table 11: Typical Tx/Rx Current Consumption for Wi-Fi – 2.4 GHz (2SS/PCIe)
| Mode | Rate | Setting Power in dBm | Current in mA | |
| Tx | Rx | |||
| 11b | 1 Mbps | 17.0 | 720 | 120 |
| 11g | 6 Mbps | 16.0 | 640 | 120 |
| 11n | MCS0 | 15.0 | 590 | 130 |
Table 12: Typical Tx/Rx Current Consumption for Wi-Fi – 5 GHz (2SS/PCIe)
| Mode | Rate | Setting Power in dBm | Current in mA | |
| Tx | Rx | |||
| 11a | 6 Mbps | 14.0 | 640 | 140 |
| 11n/ac-20 | MCS0 | 14.0 | 650 | 150 |
| 11n/ac-40 | MCS0 | 13.0 | 610 | 170 |
| 11n/ac-80 | MCS0 | 12.0 | 590 | 190 |
Table 13 and Table 14 describe the typical Tx/Rx current consumption in WLAN SDIO mode for 2.4 GHz and 5 GHz.
Table 13: Typical Tx/Rx Current Consumption for Wi-Fi – 2.4 GHz (2SS/SDIO
| Mode | Rate | Setting Power in dBm | Current in mA | |
| Tx | Rx | |||
| 11b | 1 Mbps | 17.0 | 700 | 85 |
| 11g | 6 Mbps | 16.0 | 620 | 90 |
| 11n | MCS0 | 15.0 | 570 | 90 |
Table 14: Typical Tx/Rx Current Consumption for Wi-Fi – 5 GHz (2SS/SDIO)
| Mode | Rate | Setting Power in dBm | Current in mA | |
| Tx | Rx | |||
| 11a | 6 Mbps | 14.0 | 600 | 110 |
| 11n/ac-20 | MCS0 | 14.0 | 610 | 120 |
| 11n/ac-40 | MCS0 | 13.0 | 560 | 140 |
| 11n/ac-80 | MCS0 | 12.0 | 540 | 160 |
5.2.2 Bluetooth
Conditions:
- VBAT = 3.3V, VIO = 1.8V
- Host IF: UART
- Combo FW: 16.80.205p146
- Current definition
Figure 6: Typical Tx/Rx Current Consumption – Bluetooth
Table 15 describes the typical Tx/Rx current consumption for Bluetooth.
Table 15: Typical Tx/Rx Current Consumption – Bluetooth
| Mode | Rate | Setting Power in dBm | Current in mA | |
| Tx | Rx | |||
| BR | DH5 | 3.0 | 70 | 70 |
| EDR | 3DH5 | 0 | 70 | 70 |
| LE | LE | 3.0 | 70 | 70 |
5.3 Typical Sleep Current Consumption
This section describes the typical sleep current consumption for Wi-Fi and Bluetooth.
5.3.1 WLAN
Conditions:
- VBAT = 3.3V, VIO = 1.8V
- Target: NXP iMX8MQ-EVK (MCIMX8M-EVK)
- WLAN FW: W16.68.10.p56
- Beacon Interval = 100 ms
- SDIO Signal = SDR104 mode @1.8V VIO
- SD Clock off/on (# mlanutl mlan0 sdioclock0, #mlanutl mlan0 sdioclock1)
Table 16 describes the typical sleep current consumption data for Wi-Fi.
Table 16: Typical Sleep Current Consumption – Wi-Fi
| Band | Mode | VBAT (3.3V) in mA PCIe mode | VBAT (3.3V) in mA SDIO (Clock off) | VBAT (3.3V) in mA SDIO (Clock on) |
| Chip deep sleep | 0.51 | 0.90 | 1.28 | |
| 2.4 GHz | IEEE Power Save: DTIM1 | 4.07 | 3.30 | 3.67 |
| IEEE Power Save: DTIM3 | 1.70 | 1.69 | 2.08 | |
| IEEE Power Save: DTIM5 | 1.22 | 1.37 | 1.76 | |
| 5 GHz | IEEE Power Save: DTIM1 | 2.23 | 2.53 | 2.92 |
| IEEE Power Save: DTIM3 | 1.08 | 1.44 | 1.83 | |
| IEEE Power Save: DTIM5 | 0.85 | 1.22 | 1.61 |
5.3.2 Bluetooth
Conditions:
- VBAT = 3.3V, VIO = 1.8V
- Target: NXP iMX6SoloX-SABRE (MCIMX6SX-SDB)
- WLAN FW: W16.68.10.p22
- SDIO Signal = SDR104 mode @1.8V VIO
- SD Clock off/on (# mlanutl mlan0 sdioclock0, #mlanutl mlan0 sdioclock1)
Table 17 describes the parameters for typical sleep current consumption for Bluetooth
Table 17: Typical Sleep Current Consumption – Bluetooth
| Wi-Fi SDIO | Current Consumption VBAT (3.3V) in mA | |||
| 50 MHz | 200 MHz | |||
| Disable | Enable | Disable | Enable | |
| SDIO Mode | 0.29 | 0.36 | 0.95 | 1.34 |
5.4 Typical Bluetooth Advertise Current Consumption
This section describes the typical Bluetooth current consumption.
Conditions:
- VBAT = 3.3V, VIO = 1.8V
- Target: NXP iMX6SoloX-SABRE (MCIMX6SX-SDB)
- Bluetooth FW: 16.26.10.p56
Table 18 describes the typical Bluetooth advertise current consumption.
Table 18: Typical Bluetooth Advertise Current Consumption
| Current Consumption VBAT (3.3V) in mA | ||||
| 50 MHz | 200 MHz | |||
| Disable | Enable | Disable | Enable | |
| Bluetooth page scan | 0.72 | 0.77 | 1.43 | 1.83 |
| Bluetooth page and inquiry scan | 0.80 | 1.68 | 1.58 | 1.72 |
| Bluetooth ACL / Sniff mode interval = 1.28sec | 0.40 | 0.42 | 0.95 | 1.30 |
| Bluetooth LE advertise / Interval = 1.28sec | 0.35 | 0.39 | 1.16 | 1.80 |
5.5 Typical Throughput
Test Configuration:
- VBAT = 3.3V, VIO = 1.8V
- Target: NXP i.MX8MQuad EVK (Part Number – MCIMX8M-EVK)
- WLAN Firmware (PCIe): 16.92.10.p213.4
- WLAN Firmware (SDIO): 16.92.10.p219.5
- Access Point: ASUS RT-AX88U
- Distance between Access Point and the Target is around 3 ft.
- UDP commands: Bit rate was set at more than 20% of observed corresponding TCP throughput.
- Sample UDP command:
iperf3 <server-ip-addr> -u -b <20%-of-TCP>M -P1 -t 60
Table 19 and Table 20 describes the typical throughput values for WLAN in PCIe and SDIO modes.
Table 19: Typical Throughput – Wi-Fi PCIe Mode
| Mode | TCP Throughput in Mbps | UDP Throughput in Mbps | ||
| Tx | Rx | Tx | Rx | |
| 2.4 GHz 11n HT20 | 119 | 122 | 121 | 126 |
| 5 GHz 11ac VHT80 | 687 | 598 | 741 | 745 |
Table 20: Typical Throughput – Wi-Fi SDIO Mode
| Mode | TCP Throughput in Mbps | UDP Throughput in Mbps | ||
| Tx | Rx | Tx | Rx | |
| 2.4 GHz 11n HT20 | 121 | 116 | 125 | 117 |
| 5 GHz 11ac VHT80 | 433 | 444 | 469 | 499 |
References
Table 21 reviews all the key reference documents that the user may like to refer to.
Table 21: Reference Table
| Support Site | Notes |
| Murata Type 1YM Module Datasheet | Murata Type 1YM module datasheet (type1ym.pdf) |
| Murata Type 1YM Module Footprint | Murata Type 1YM module footprint (type1ym_module_footprint_topview.dxf) |
| Murata Type 1YM Antenna | Murata Type 1YM module antenna (Type1YM-u-FL.DXF) |
| Murata’s GitHub | Murata GitHub link for Linux transmit power files |
| wireless-regdb | Regulatory database used by Linux |
| Linux User Guide | Murata Linux User Guide for NXP modules (Murata Wi-Fi & BT (NXP) Solution for i.MX Linux User Guide.pdf). Murata website to be updated soon. |
In case Murata website does not have the updated document, please refer to the Connectivity Module page on the Murata Community Forum. This contains a pinned post with all the updated documents.
Technical Support Contacts
Table 22 lists all the support resources available for the Murata Wi-Fi/BT solution.
Table 22: List of Support Resources
| Support Site | Notes |
| Murata Community Forum | Primary support point for technical queries. This is an open forum for all customers. Registration is required. |
| Murata i.MX Landing Page | No login credentials required. Murata documentation covering hardware, software, testing, etc. is provided here. |
| Murata uSD-M.2 Adapter Landing Page | Landing page for uSD-M.2 Adapter. In conjunction with Murata i.MX Landing Page, this should provide the user with comprehensive getting started documentation. |
| Murata Module Landing Page | No login credentials required. Murata documentation covering all Infineon-based Wi-Fi/BT modules is provided here. |
Revision History
| Revision | Date | Changed Item | Comment |
| 1.0 | Apr. 29, 2021 | First issue | |
| 2.0 | Oct.1, 2021 | Top Page 2.2 Hardware block diagram 5.4 Typical Sleep Current Consumption 5.5 Typical Bluetooth Advertise Current Consumption |
· Updated 3D graphics. · Updated block diagram. · Added 5.4.2 Bluetooth · Added this section |
| 3.0 | Dec.24, 2021 | 3. Reference Circuitry | · Corrected DC blocker position of PCIE |
| 4.0 | Jan 26, 2023 | Updated to new format | · Moved transmit power table for all region to the 1YM datasheet. · Added the antenna section 3.5.3. · Removed external sleep clock requirements section 3.3. It is present in datasheet. |
| 5.0 | Sep 12, 2023 | 3.5.1 PCB Type Di-pole Antenna with the Co-axial Connector | · Added an example of C1PC antenna list |
| 6.0 | Mar 04, 2025 | 3.1 Reference Circuitry 3.5 Recommended Antenna Design and Configuration 3.5.3 PCB Stack-Up 5.4 Typical Bluetooth Current Consumption 5.5 Typical Throughput |
· Minor update · Added an additional registered antennas in Japan Radio Law certification (Table 4). · Added Info Note · Removed. Merged to Radio Law Approval application note. · Modify the wording: Underneath of u.FL/MHF connector. · Updated · Updated |
Copyright © Murata Manufacturing Co., Ltd. All rights reserved. The information and content in this document are provided “as-is” with no warranties of any kind and are for informational purpose only. Data and information have been carefully checked and are believed to be accurate; however, no liability or responsibility for any errors, omissions, or inaccuracies is assumed.
The Bluetooth® word mark and logos are registered trademarks owned by Bluetooth SIG, Inc. Other brand and product names are trademarks or registered trademarks of their respective owners.
Specifications are subject to change without notice.
©2020 by Murata Manufacturing Co., Ltd.
Mar 04, 2025
E2B-02-1367
Rev. 6.0
www.murata.com
Documents / Resources
 |
muRata LBEE5XV1YM Wi-Fi Plus Bluetooth Module [pdf] Instruction Manual LBEE5XV1YM, LBEE5XV1YM Wi-Fi Plus Bluetooth Module, Wi-Fi Plus Bluetooth Module, Bluetooth Module, Module |