which is an App PandwaRF is a RF analysis tool with a sub-1 GHz wireless transceiver controlled by a smartphone or a PC. Its purpose is to capture, display & transmit RF data very easily. It can be connected to an Android smartphone using BLE or USB, and to Linux using USB. It is based on the well-known RfCat & Yard Stick One tools with the Texas Instruments CC1111 RF transceiver, but with a lot of new features, making PandwaRF the perfect portable RF analysis tool.

https://play.google.com/store/apps/details?id=com.comthings.pandwarf

so here it is next deliever on the global market the wiced (the github code previouse posted) by Cypress, aqquired to Broadcom IoT ....for 550 million...(see next post)

my wild guess for the embebbed software is wiced-emw3165, for this electronic board we're talking about Support for various MCU host platforms- ST Microelectronics STM32F2xx (in this case STM32F7) the great about this is Wi-Fi & Bluetooth SmartBridge Features: Authenticate to Wi-Fi Access Points with the following security types: Open, WEP-40, WEP-104, WPA (AES & TKIP), WPA2 (AES, TKIP & Mixed mode)

The WICED SDK provides a full compliment of application level APIs, 
libraries and tools needed to design & implement secure embedded wireless
networking applications. 

Major features of the WICED SDK include ...
  - Low-footprint embedded Wi-Fi Driver with Client (STA), softAP and Wi-Fi Direct
  - Wi-Fi <-> Bluetooth SmartBridge 
  - Various RTOS/TCP stack options including
    - ThreadX/NetX (IPv4), ThreadX/NetX Duo (IPv6), FreeRTOS/LwIP (IPv4)
  - Support for various Broadcom Wi-Fi & combo chips
    - BCM4390 Integrated Apps + Wi-Fi SoC
    - BCM43909 Integrated Apps + Wi-Fi SoC
    - BCM43362 Wi-Fi SoC
    - BCM43364 Wi-Fi SoC
    - BCM43341 Wi-Fi SoC
    - BCM43438 Wi-Fi SoC
    - BCM43341 Wi-Fi + Bluetooth combo SoC
  - Support for various MCU host platforms
    - ST Microelectronics : STM32F2xx, STM32F4xx
    - Atmel : AT91SAM4S16B
    - Freescale : K61
    - NXP : LPC17xx, LPC18xx
  - RTOS & Network abstraction layer with a simple API for UDP, TCP, HTTP, HTTPS communications
  - SSL/TLS Security Library integrated with an HTTPS library for secure web transactions
  - WICED Application Framework including Bootloader, OTA Upgrade and Factory Reset
  - Automated Wi-Fi Easy Setup using one of several methods
    - SoftAP & Secure HTTP server
    - Wi-Fi Protected Setup
    - Apple Wireless Accessory Configuration (WAC) Protocol
  - Simple API to provide access to MCU peripherals including UART, SPI, I2C, Timers, RTC, ADCs, DACs, etc
  - Support for multiple toolchains including GNU and IAR
  - Support for Apple AirPlay and HomeKit
 
The WICED SDK release is structured as follows:
  apps          : Example & Test Applications
  doc           : API & Reference Documentation
  include       : WICED API, constants, and defaults 
  libraries     : Bluetooth, daemons, drivers, file systems, inputs, and protocols
  platforms     : Evaluation board support package, including Eval Board and Module Schematics
  resources     : Binary and text based objects including scripts, images, and certificates
  tools         : Build tools, compilers, debugger, makefiles, programming tools etc.
  tools/drivers : Drivers for WICED evaluation boards
  WICED         : WICED core components (RTOS, Network Stack, Wi-Fi Driver, Security & Platform libraries)
  WICED/WWD     : The WICED Wi-Fi Driver (equivalent to the Wiced directory in previous SDK-1.x releases) 
  README.txt    : This file
  CHANGELOG.txt : A log of changes for each SDK revision
 

to compile, download and run the Wi-Fi scan application on the Broadcom BCM943362WCD4 evaluation platform, 
enter the following text on a command line (a period character is used to reference applications 
in sub-directories) :
$> make snip.scan-BCM943362WCD4 download run

The default RTOS and Network Stack components are defined in the WICED configuration makefile  
at /tools/makefiles/wiced_config.mk. The default I/O bus component is defined in the platform
makefile at /platforms//.mk. Defaults may be bypassed by specifying the 
component as part of the build string if desired as shown in the following example.
$> make snip.scan-BCM943362WCD4-FreeRTOS-LwIP-SDIO download run
       
Source code, headers and reference information for supported platforms are available 
in the /platforms directory. Source code, headers, linker scripts etc that 
are common to all platforms are available in the /WICED/platform directory.


Supported Features
---------------------------------------------------------------------
Wi-Fi & Bluetooth SmartBridge Features
 * Scan and associate to Wi-Fi access points
 * Authenticate to Wi-Fi Access Points with the following security types:
   Open, WEP-40, WEP-104, WPA (AES & TKIP), WPA2 (AES, TKIP & Mixed mode)
 * AP mode with support for security types : Open, WPA, WPA2
 * Concurrent AP & STA mode (AP mode limited to 3 concurrent connected clients)
 * Wi-Fi Direct
 * WPS 1.0 & 2.0 Enrollee & Registrar (Internal Registrar only)
 * Wi-Fi APIs : Network keep alive, packet filters
 * Host <-> Wi-Fi SDIO & SPI interface
 * Bluetooth SmartBridge with multiple connections including the
   following features: Whitelist, Bond Storage, Attribute Caching, 
   GATT Procedures, Configurable Maximum Concurrent Connections, Directed 
   Advertisements, Device address initialisation, Passkey entry
 * Host <-> Wi-Fi via Memory to Memory DMA engine

Bluetooth Features
 * A2DP v1.2 (Advanced Audio Distribution Profile)
   - A2DP Sink Functionality
   - SBC Decoder
 * AVRCP (Audio/Video Remote Control Profile)
   - AVRCP Controller v1.0
   - AVRCP Target v1.4 (Absolute Volume)
 *  Handsfree profile (Handsfree role)
   - HFP v1.6
   - Accept/Reject/End incoming call
   - Outgoing call – Last number dial
   - Support for inband ringtone
   - Two-way calling
   - Caller-ID support
 * Man-Machine-Interface via buttons
   - AVRCP play/pause/Skip-forward/Skip-backward
   - A2DP Volume Up/Down
   - Connect to previously connected device
   - HFP Accept/Reject/End incoming call and Last number dial
 * SDAP (Service Discovery Application Profile)
 * GAP (Generic Access Profile)

RTOS & Network Stack Support
 * FreeRTOS / LwIP    (full source)
 * ThreadX  / NetX    (object file; free for use with WICED *ONLY*)
 * ThreadX  / NetXDuo (object file; free for use with WICED *ONLY*)

Networking Features (IPv4 & IPv6)
 * ICMP (Ping)
 * ARP
 * TCP
 * UDP 
 * IGMP (Multicast)
 * IPv6 NDP, Multicast
 * DHCP (Client & Server)
 * DNS (Client & Redirect Server)
 * mDNS/DNS-SD Zeroconf Network Discovery (Broadcom Gedday)
 * TLS1.0/1.1/1.2 (object file with host abstraction layer; free for use with WICED *ONLY*)
 * HTTP / HTTPS (Client & Server)
 * SNTP
 * SMTP

Application Features
 * Apple AirPlay (requires Apple authentication co-processor; available to Apple MFi licensees *ONLY*) 
 * Apple HomeKit (available to Apple MFi licensees *ONLY*)
 * Bluetooth Audio
 * Peripheral interfaces
   * GPIO
   * Timer / PWM
   * UART
   * SPI
   * I2C
   * RTC (Real Time Clock)
 * Xively "Internet of Things" protocol

* WICED Application Framework
   * Bootloader
   * Device Configuration Table (region in flash to store AP, security credentials, TLS certs, serial number, Wi-Fi country code, etc)
   * OTA upgrade
   * Factory reset
   * Automated configuration via softAP & webserver
   * Apple Wireless Accessory Configuration (WAC) protocol (available to Apple MFi licensees *ONLY*)
   * System Monitor to manage the watchdog

Toolchains
 * GNU make
 * IAR

Hardware Platforms
 BCM43362
   * BCM943362WCD4  : Broadcom WICED Module with STM32F205 MCU mounted on BCM9WCD1EVAL1
   * BCM943362WCD6  : Broadcom WICED Module with STM32F415 MCU mounted on BCM9WCD1EVAL1
   * BCM943362WCD8  : Broadcom WICED Module with Atmel SAM4S16B MCU mounted on BCM9WCD1EVAL1
   * BCM9WCDPLUS114 : WICED+ Eval Board (includes BCM43362+STM32F205 WICED+ Module and BCM20702 Bluetooth module)
   * BCM9WCD1AUDIO  : Broadcom WICED Audio Evaluation Board (includes BCM43362, STM32F415, WM8533 audio DAC, and BCM20702 Bluetooth module)
 BCM943364
   * BCM943364WCD1  : Broadcom WICED Module with STM32F215 MCU mounted on BCM9WCD1EVAL1
   * BCM943364WCDA  : Broadcom WICED Module with Atmel SAM4S16B MCU mounted on BCM9WCD1EVAL1
 BCM943341
   * BCM943341WCD1  : Broadcom BCM43341-based WICED Module with STM32F417 MCU mounted on BCM9WCD5EVAL1
 BCM4390
   * BCM94390WCD2   : Broadcom BCM4390 SiP-based WICED Module on BCM9WCD3EVAL1
 BCM43909
   * BCM943909WCD1  : Broadcom BCM43909 SiP-based WICED Module on BCM943909WCDEVAL_1
https://github.com/kamejoko80/wiced-emw3165

OK...I've been working...more than 45 minutes to get this , this micro tag NSA we're talking about Snowden , can be embebbed with wifi connection , audio, camera, flash, and so on...what I didn't get yet, is the software

Product description

1. MCU core board connector: for easily connecting the Core746I
2. Arduino interface: for connecting Arduino shields
3. DCMI interface: for connecting camera
4. 8-bit FMC interface: easily connects to peripherals such as NandFlash
5. ULPI interface: for connecting high-speed USB peripheral (the STM32F746I integrates USB HS controller without any PHY device) 
6. LCD interface 1: for connecting 10.1inch LCD, 7inch LCD
7. LCD interface 2: for connecting 4.3inch LCD
8. SAI1 interface: for connecting audio modules like UDA1380 module
9. ICSP interface: Arduino ICSP
10. SPI1/SPI2 interfaces: 
easily connects to SPI peripherals such as DataFlash (AT45DBxx, W25QXX), SD card, MP3 module, etc. 
easily connects to AD/DA modules (SPI1 features AD/DA alternative function) 
11. Ethernet interface: for connecting Ethernet modules
12. I2S2/I2S3/I2C1 interface: easily connects to I2S peripherals such as audio module, etc. 
13. USART1 connector: USB to UASRT via the onboard convertor CP2102 
14. QUADSPI interface: 4-wires SPI interface (the F7 series latest peripheral interface), for connecting serial Flash modules like W25QXX Board
15. SDMMC interface: for connecting Micro SD module, features much faster access speed rather than SPI
16. USART3 interface: easily connects to RS232, RS485, USB TO 232, etc. 
17. CAN2 interface: for connecting CAN modules
18. CAN1 interface: for connecting CAN modules
19. I2C1/I2C4 interface: easily connects to I2C peripherals such as I/O expander (PCF8574), EEPROM (AT24Cxx), 10 DOF IMU Sensor, etc. 
20. MCU pins connector: all the MCU I/O ports are accessible on expansion connectors for further expansion
21. 5V DC jack
22. 5V/3.3V power input/output: usually used as power output, also common-grounding with other user board

https://www.amazon.com/Next-Open746I-C-Package-STM32F7-Development/dp/B01EHK88Z2

So, NSA gadgets hidden on coins, or currency ...

you want secret transmissions?...(they have it) could we transmit "Utilizing home audio tweeter piezoelectric elements and an 8bit microcontroller data was encoded into an acoustic wave which was transmitted through water and detected by another microcontroller using an identical piezoelectric element as a microphone" ? do you want it? TOR network?

   Inexpensive Underwater Data Communication.pdf by Elsa Cristina David on Scribd

Applications, among others... Send/Receive data...piezo air transducer!....here we have an external drive (!!) 25 p~p (peak to peak voltage waveform)

https://www.steminc.com/PZT/en/piezo-air-transducer-112-khz

http://www.communica.co.za/catalog/Details/P4066208523

For the countries interessested ...on transfering data and packets crossing the faraday cage ...where their servers are protected

Data Transfer and Wireless Changing Over Electro Magnetic Field

 

   Data Transfer and Wireless Changing Over Electro Magnetic Field by Elsa Cristina David on Scribd

well...last resource for their protection is...Transmitting data and power through a Faraday Cage boundary

While the Faraday Cage effect is essential in many contexts – preventing leakage from microwave ovens, lightning strike protection, screening data cables – TTP’s Fluxor technology will have major benefits for power and data transfer through metal shielding. TTP is already using the technology for monitoring fluid levels in steel pipes, taking readings from medical implants and measuring data from inside high-performance F1 engines.

The Fluxor method creates a ‘window’ for electromagnetic transmission of power and data by applying a strong DC magnetic field, which lines up the magnetic dipoles in the material to ‘saturate’ a small area of the metal screen. This reduces the permeability and increases penetration to make it possible to transfer electromagnetic power and signals. Experiments conducted by TTP using steels from 5-15mm thick show that the optimum operating frequency range is in the region of 400-500Hz.

In a typical operating scenario, a portable interrogator unit with a permanent magnet or electromagnet could be placed adjacent to a fixed sensor, through a metal wall. A Fluxor window is opened to transmit power to energise the sensor and transmit a signal back – all without the need for physical openings in the enclosure.

http://www.eedesignnewseurope.com/news/transmitting-data-and-power-through-faraday-cage-boundary

Arduino ESP8266 IoT : Relay Control Internet .....drone defender...

http://anodas.lt/elektronika/ENC28J60-Ethernet-Module

UFED Ultimate / PA Extract and decode every ounce of data within digital devices. Delve deep using leading-edge forensic examination capabilities and thoroughly review logical, file system and physically extracted data to discover critical evidence

https://www.cellebrite.com/en/product/solutions/extract-decode/