WT32i BLUETOOTH AUDIO MODULE DATA SHEET Monday, 18 March 2019 Version 1.3.1 VERSION HISTORY VERSION COMMENT 1.0 First version 1.1 Added example how to protect the battery by shutting down the regulators at certain voltage level 1.2 Fixed PCM pin numbering 1.21 Design check list added 1.22 UART brake signal updated 1.23 Chapter 9.3.1 added 1.24 Added note to reset section 1.3 Updated order codes and added more information about iWRAP versions. 1.3.1 Fixed one wrong build number Silicon Labs TABLE OF CONTENTS 1 Design Check List..........................................................................................................................................6 2 WT32i Product Numbering ............................................................................................................................7 3 Block diagram ................................................................................................................................................8 4 Pinout and Terminal Description ...................................................................................................................9 5 Electrical Characteristics ............................................................................................................................ 12 5.1 Absolute Maximum Ratings ................................................................................................................ 12 5.2 Recommended Operating Conditions ................................................................................................. 12 5.3 Digital Terminals.................................................................................................................................. 12 5.4 Audio Characteristics .......................................................................................................................... 13 5.4.1 ADC .............................................................................................................................................. 13 5.4.2 DAC .............................................................................................................................................. 14 5.4.3 A2DP Codecs............................................................................................................................... 14 5.5 5.5.1 RF Transceiver ............................................................................................................................ 16 5.5.2 Antenna Characteristics ............................................................................................................... 17 5.6 6 RF Characteristics ............................................................................................................................... 16 Current Consumption .......................................................................................................................... 20 Power Control and Regulation ................................................................................................................... 21 6.1 Protecting the Battery by Configuring the Module to Turn Off at Certain Voltage .............................. 23 6.2 Reset ................................................................................................................................................... 24 6.2.1 Internal POR ................................................................................................................................ 24 7 Battery Charger .......................................................................................................................................... 26 8 GPIO and AIO Functions ............................................................................................................................ 27 8.1 iWRAP supported GPIO Functions ..................................................................................................... 27 8.2 Outputting Internal Clocks ................................................................................................................... 27 8.3 Auxiliary ADC ...................................................................................................................................... 28 8.4 Software I2C Interface ........................................................................................................................ 28 9 Serial Interfaces.......................................................................................................................................... 29 9.1 UART Interface.................................................................................................................................... 29 9.1.1 Resetting Through UART Break Signal ....................................................................................... 30 9.1.2 UART Configuration While Reset is Active .................................................................................. 30 9.1.3 UART Bypass Mode .................................................................................................................... 30 9.2 USB Interface ...................................................................................................................................... 31 9.3 Programming and Debug Interface (SPI) ............................................................................................ 32 9.3.1 10 Multi-slave Operation ................................................................................................................... 32 Audio Interfaces ...................................................................................................................................... 33 10.1 10.1.1 Stereo Audio Codec Interface ...................................................................................................... 33 ADC .............................................................................................................................................. 33 Silicon Labs 10.1.2 DAC .............................................................................................................................................. 35 10.1.3 Microphone Input ......................................................................................................................... 36 10.1.4 Line Input ..................................................................................................................................... 37 10.1.5 Output Stage ................................................................................................................................ 38 10.1.6 Mono Operation ........................................................................................................................... 40 10.1.7 Side Tone ..................................................................................................................................... 40 10.2 PCM Interface .............................................................................................................................. 40 10.3 I2S Interface ................................................................................................................................. 40 10.4 IEC 60958 Interface ..................................................................................................................... 42 11 Design Guidelines ................................................................................................................................... 44 11.1 Audio Layout Guide ..................................................................................................................... 44 11.1.1 EMC Considerations .................................................................................................................... 44 11.1.2 Choosing Capacitors and Resistors ............................................................................................ 44 11.2 RF Layout Guide .......................................................................................................................... 45 11.3 Example Application Schematics ................................................................................................. 48 12 Physical Dimensions ............................................................................................................................... 52 13 Soldering Recommendations .................................................................................................................. 54 14 Package .................................................................................................................................................. 55 15 Certification Guidance for an End Product Using WT32i ....................................................................... 57 15.1 Bluetooth End Product Listing...................................................................................................... 57 15.2 CE Approval of an End-Product ................................................................................................... 57 15.3 FCC Certification of an End Product ............................................................................................ 58 15.3.1 Co-location with Other Transmitters ............................................................................................ 59 15.4 IC Certification of an End Product ............................................................................................... 59 15.5 MIC Japan Certification of an End Product .................................................................................. 59 16 WT32i Certifications ................................................................................................................................ 59 16.1 Bluetooth ...................................................................................................................................... 59 16.2 CE ................................................................................................................................................ 59 16.3 FCC .............................................................................................................................................. 60 16.4 IC .................................................................................................................................................. 61 16.4.1 IC .................................................................................................................................................. 61 16.5 MIC Japan .................................................................................................................................... 62 16.6 KCC (South-Korea) ...................................................................................................................... 62 16.7 Qualified Antenna Types for WT32i-E ......................................................................................... 62 Silicon Labs WT32i Bluetooth(R) Audio Module DESCRIPTION KEY FEATURES: WT32i is an audio specific Bluetooth 3.0 module with excellent radio frequency performance and enhanced audio features, enabling a best in class Bluetooth audio experience. In addition to a certified Bluetooth radio and software stack, WT32i also contains a DSP, stereo audio codec, and battery charger making it ideal for fixed and portable audio applications. WT32i includes Bluegiga's iWRAP6 Bluetooth stack software which implements A2DP, AVRCP v.1.5 profiles and supports aptX(R) and AAC audio codecs for stereo audio applications. For hands-free applications iWRAP6 software also supports HFP v.1.6, HSP, MAP and PBAP and CVC(R) echo cancellation software. For data communications to Android and iOS applications iWRAP6 also implements Bluetooth Serial Port Profile (SPP) and Apple iAP profiles. WT32i is an ideal solution for developers who want to quickly integrate the latest Bluetooth audio technologies without the time and costs typically involved with a Bluetooth audio chipset design. APPLICATIONS: * Bluetooth 3.0 compliant * Excellent Radio Performance o Transmit power: +6.5 dBm o Receiver sensitivity: -90 dBm o Link budget: 96.5 dB * Integrated chip antenna antenna connector * Audio features or U.FL o Integrated DSP o 16-bit stereo codec o 44.1kHz ADC, 48kHz DAC o Analog, I2S, PCM, SPDIF, and microphone interfaces o Optional aptX(R) and AAC stereo audio codecs CVC(R) echo o Optional cancellation o Wide Band Speech * Built-in battery charger * UART host interface * 802.11 co-existence interface * Stereo speakers and sound bars * 10 software programmable IO pins * Hi-Fi devices * Operating voltage: 1.8V to 3.6V * Hands-free kits * Temperature range: -40C to +85C * Stereo headsets * Bluetooth, CE, FCC, IC, Korea and Japan qualified * Integrated iWRAP6 Bluetooth stack o 13 Bluetooth profiles o Apple iAP1 compatibility Figure 1: WT32i Bluetooth Audio Module Silicon Labs and iAP2 1 Design Check List POWERING THE MODULE Make sure that VRE_ENA is connected correctly Use iWRAP command SET CONTROL VREGEN command to configure the VREG_ENA pin according to the HW Reserve test points for SPI interface for debugging and FW updates Battery Voltage (2.7V...4.4V) VDD_BAT VREG_ENA On/Off cntrl The internal power on reset does not work properly if the host pulls the reset line low during boot. To prevent this, place a diode to the reset input. IN LDO EN (1.8V...3.6V) VDD_IO Battery Voltage (2.7V...4.4V) VDD_BAT VREG_ENA Host CPU On/Off cntrl IN LDO EN (1.8V...3.6V) VDD_IO WT32i GPIO Reset RF LAYOUT Make sure that the layout for the antenna is done as instrcucted. Board edge Min 15mm Min 15mm 6mm Metal clearance area GND plane indentation 2mm GND plane indentation max 5.9 mm AUDIO DESIGN AND LAYOUT See the example schematics on pages 49 -52 Avoid using single ended audio traces. Always use differential audio signaling when possible Use solid GND plane and make sure that all the GND pins are connected to it by placing a GND via right next to any GND pins. When routing single ended audio traces, make sure that the return current (i.e. GND) follows the traces all the way from start to the end Differential audio signalstarces are traced parallel Differential audio are routed to make sure they have perfect common mode symmetrically and parallel rejection . All the audio traces are routed on a solid GND plane. DO NOT COMPROMISE AUDIO ROUTING Silicon Labs 2 WT32i Product Numbering Product code Description WT32i-A-AI61 WT32i Bluetooth Module with internal chip antenna and iWRAP 6.1.0 (build 1022) Bluetooth software WT32i-A-AI61-APTX WT32i Bluetooth Module with internal chip antenna and aptX(R) audio codec capable iWRAP 6.1.0 (build 1024) Bluetooth software. WT32i-A-AI61IAP WT32i Bluetooth Module with internal chip antenna and Apple iAP capable iWRAP 6.1.0 (build 1055) Bluetooth software. Available only to Apple MFI licensees. Contact www.silabs.com/about-us/contact-sales for more information. WT32i-E-AI61 WT32i Bluetooth Module with U.FL connector and iWRAP 6.1.0 (build 1022) Bluetooth software WT32i-E-AI61-APTX WT32i Bluetooth Module with U.FL connector and aptX(R) audio codec capable iWRAP 6.1.0 (build 1024) Bluetooth software. WT32i-E-AI61IAP WT32i Bluetooth Module with U.FL connector and Apple iAP capable iWRAP 6.1.0 (build 1055) Bluetooth software. Available only to Apple MFI licensees. Contact www.silabs.com/about-us/contact-sales for more information. DKWT32i-A WT32i development kit Silicon Labs 3 Block diagram Flash BC05-MM UART/USB RAM Antenna Balanced filtter 2.4 GHz Radio Baseband DSP PIO I/O Audio In/Out MCU PCM/I2S Kalimba DSP SPI XTAL Reset circuitry Figure 2: Block Diagram of WT32i BC05-MM The BlueCore(R)5-Multimedia External is a single-chip radio and baseband IC for Bluetooth 2.4GHz systems. It provides a fully compliant Bluetooth v3.0 specification system for data and voice. BlueCore5-Multimedia External contains the Kalimba DSP coprocessor with double the MIPS of BlueCore3-Multimedia External, supporting enhanced audio applications. XTAL Ther reference clock of WT32i is generated with 26 MHz crystal. All BC05-MM internal digital clocks are generated using a phase locked loop, which is locked to the frequency of either the 26 MHz crystal or an internally generated watchdog clock frequency of 1kHz. RESET CIRCUITRY The internal reset circuitry keeps BC05-MM in reset during boot in order for the supply voltages to stabilize. This is to prevent corruption of the flash memory during booting. Please see chapter 6.1 for more detailed description. BALANCED FILTER The internal balanced filter provides optimal impedance matching and band pass filtering in order to achieve lowest possible in-band and out-of-band emissions. ANTENNA The antenna is a ceramic chip antenna with high efficiency. The antenna is insensitive to surrounding dielectric materials and requires only a small clearance underneath which makes it compatible with previous WT32I designs and well suitable for designs with high density. FLASH 16 Mbit flash memory is used for storing the Bluetooth protocol stack and Virtual Machine applications. It can also be used as an optional external RAM for memory-intensive applications. Silicon Labs 4 Pinout and Terminal Description 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 AUDIO_OUT_P_LEFT AUDIO_OUT_N_LEFT GND AUDIO_OUT_P_RIGHT AUDIO_OUT_N_RIGHT AUDIO_IN_N_LEFT AUDIO_IN_P_LEFT GND AUDIO_IN_N_RIGHT AUDIO_IN_P_RIGHT MIC_BIAS GND VDD_CHG VDD_BAT LED0 SPI_MOSI SPI_MISO SPI_CLK SPI_NCSB GND GND RESET UART_NRTS UART_NCTS PIO8 PIO7 PIO6 PIO5 PIO4 PCM_IN PCM_OUT PCM_SYNC PCM_CLK 18 19 20 21 22 23 24 25 26 27 28 29 30 VREG_ENA GND GND GND AIO0 AIO1 PIO0 PIO1 PIO2 PIO3 USB_DUSB_D+ PIO9 PIO10 UART_RXD UART_TXD VDD_IO 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 Figure 3: WT32i Pin Number Pin Name Pad Type Description 1 VREG_ENA Input SW configurable enable pin for the internal regulators 2-4, 18, 31, 39, 43, 48 GND GND GND 17 VDD_IO Power supply 1.7V - 3.6V power supply for the serial interfaces and GPIOs 37 VDD_BAT Power supply / Charger output 2.7V - 4.4V supply voltage for the internal regulators and output of the battery charger 38 VDD_CHG Power supply Nominal 5V supply voltage for the battery charger Table 1: Supply Terminal Descriptions Silicon Labs Page 9 of 63 Pin Number Pin Name 19 RESET 5 AIO0 Pin Type Description RESET Active high reset. If not used, leave floating. When connected, make sure that the reset is either pulled high or floating (connected to high impedance) during boot. Configurable I/O AIO0 and AIO1 can be used to read the voltage level through the internal ADC (refer to iWRAP User Guide for details). AIO pins can also be configured to be used as general digital IO pins through PS settings. Internal clocks can be routed out through AIO pins by setting corresponding PS settings. Note that the AIO pins are powered from internal 1.5V supply so the maximum voltage level of the AIO pins is 1.5V. General purpose IO's can be configured with iWRAP for various functions. Each IO can be configured individually as output or input with strong or weak pull-up/-down. Using particular PS setting GPIO pins can be used to implement WiFi co-existence signaling between WT32i and a WiFi radio. Software I2C interface can be implemented for slow I2C functions such as configuring external audio codec or display. 6 AIO1 7 8 9 10 13 14 22 23 24 25 26 PIO0 PIO1 PIO2 PIO3 PIO9 PIO10 PIO8 PIO7 PIO6 PIO5 PIO4 Configurable CMOS I/O 11 USB_D- I/O 12 USB_D+ I/O 15 UART_RXD CMOS Input, weak internal pull-down UART data input 16 UART_TXD CMOS output, tristate, weak internal pull-up UART data output 20 UART_NRTS CMOS output, tristate, weak internal pull-up UART request to send, active low 21 UART_NCTS CMOS Input, weak internal pull-down UART clear to send, active low 32 SPI_NCSB 33 SPI_CLK USB data minus USB data plus with selectable internal 1.5k pull-up resistor CMOS Input, weak internal pull-down CMOS Input, weak internal pull-down SPI chip select SPI clock Silicon Labs Page 10 of 63 34 SPI_MISO 35 SPI_MOSI 36 LED0 CMOS Input, weak internal pull-down CMOS output, tristate, weak internal pull-down SPI data input SPI data output Open drain output LED driver Table 2: Terminal Descriptions Pin Number Pin Name Pin Type 40 41 42 44 45 46 47 49 50 MIC_BIAS AUDIO_IN_P_RIGHT AUDIO_IN_N_RIGHT AUDIO_IN_P_LEFT AUDIO_IN_N_LEFT AUDIO_OUT_N_RIGHT AUDIO_OUT_P_RIGHT AUDIO_OUT_N_LEFT AUDIO_OUT_P_LEFT Analog Analog Analog Analog Analog Analog Analog Analog Analog 27 PCM_IN / I2S IN 28 PCM_OUT / I2S_OUT 29 PCM_SYNC / I2S_WS Bidirectional, weak internal down PCM sync or I2S word select. WT32i can operate as a PCM/I2S master providing the sync or as a slave receiving the sync 30 PCM_CLK / I2S_SCK Bidirectional, weak internal down PCM or I2S clock. WT32i can operate as a PCM/I2S master providing the clock or as a slave receiving the clock. Description CMOS input, weak internal pull-down CMOS outptu, tristate, weak internal pull-down PCM or I2S data input PCM or I2S data output Table 3: Audio Terminal Descriptions Silicon Labs Page 11 of 63 5 Electrical Characteristics 5.1 Absolute Maximum Ratings Storage temperature range Operating temperature range VDD_IO VDD_BAT VDD_CHG Digital Terminal voltages AIO voltages Min Max Unit -40 -40 -0.4 -0.4 -0.4 VSS - 0.4V VSS - 0.4V +85 +85 3.6 4.4 6.5 VDD + 0.4V 1.9V C V V V V V C Table 4: Absolute Maximum Ratings 5.2 Recommended Operating Conditions Storage temperature range Operating temperature range VDD_IO VDD_BAT VDD_CHG Digital Terminal voltages AIO voltages Min Max Unit -40 -40 1.7 2.7 0 0 0 +85 +85 3.6 4.4 6.5 VDD 1.5V C V V V V V C Table 5: Recommended Operating Conditions 5.3 Digital Terminals Input/Output Characteristic Min Max Unit VIL input logic level low VIL input logic level high -0.3 0.625 x VDD 0.25 x VDD VDD + 0.3 V V VOL output logic level low, IOL = 4.0mA VOL output logic level high, IOL = -4.0mA Strong pull-up Strong pull-down Weak pull-up Weak pull-down 0 0.75 x VDD -100 10 -5 0.2 0.125 VDD -10 100 -0.2 5 V V A A A A Table 6: Digital Terminal Characteristics Silicon Labs Page 12 of 63 5.4 Audio Characteristics 5.4.1 ADC Parameter Conditions Min Typ Max Unit - - - 16 Bits - 8 - 44.1 kHz 8kHz - 79 - dB 11.025kHz - 77 - dB 16kHz - 76 - dB 22.050kHz 32kHz - 76 75 - dB dB 44.1kHz - 75 - dB Input full scale at maximum gain (differential) - 4 - mV rms Input full scale at minimum gain (differential) - 800 - mV rms 3dB Bandwidth - 20 - kHz Microphone mode input impedance - 6.0 - kHz THD+N @ 30mV rms input - 0.04 - % Resolution Input Sample Rate, Fsample Fsample Signal to Noise Ratio, SNR Table 7: ADC characteristics Silicon Labs Page 13 of 63 5.4.2 DAC Parameter Conditions Min Typ Max Unit - - - 16 Bits - 8 - 48 kHz 8kHz - 95 - dB 11.025kHz - 95 - dB 16kHz - 95 - dB 22.050kHz 32kHz - 95 95 - dB dB 44.1kHz - 95 - dB - 750 - mV rms Resistive 16 - O.C. Capacitive - - 500 pF THD+N 16 Load - - 0.1 % THD+N 100 Load - - 0.01 % Resolution Output Sample Rate, Fsample Fsample Signal to Noise Ratio, SNR Output Full Voltage Swing (differential) Allowed Load Table 8: DAC Characteristics 5.4.3 A2DP Codecs 5.4.3.1 SBC SBC codec is the default codec used for Bluetooth A2DP connections. Any Bluetooth device supporting A2DP audio profile supports SBC codec. SBC was originally design to provide reasonable good audio quality while keeping low computational complexity. SBC does not require high bit rates. Thus it works sufficiently with Bluetooth where the bandwidth and the processing power are limited. 5.4.3.2 aptX(R) The aptX is widely used in high quality audio devices. aptX can provide dynamic range up to 120 dB and it has the shortest coding delay (<2ms) than other coding algorithms. Using aptX(R) the whole system latency can be reduced significantly because unlike SBC, it does not require buffering the audio. SBC reproduces a limited audio band width whereas aptX(R) encode the entire frequency range of audio. aptX(R) is more robust and resilient coding scheme than SBC and thus re-transmits does not occur as with SBC. Both SBC and aptX(R) have flat frequency response up to 14 kHz. Up to 14 kHz both algorithms produce good quality audio with very little distortion. At frequencies higher than 14 kHz the benefit of aptX (R) becomes obvious. SBC exhibits increasing attenuation with increasing frequency but aptX (R) retains high reproduction quality. aptX(R) requires purchasing a license for each Bluetooth address and the license agreement must be done with CSR. The combination of aptX(R) license and the Bluetooth address is programmed into the module in the module production line. Silicon Labs Page 14 of 63 Figure 4: Frequency response of aptX and SBC codecs 5.4.3.3 AAC AAC (Advanced Audio Coding) achieves better sound quality than MP3 and it is the default audio format for YouTube and iPhone among others. AAC has long latency (>100ms) compared to aptX (R). Because of high processing capacity requirement for encoding, WT32i does not support AAC as A2DP source. Thus WT32i can be used for receiving (A2DP sink) AAC (from iPhone for example) but it cannot transmit AAC coded audio. Silicon Labs Page 15 of 63 5.5 RF Characteristics 5.5.1 RF Transceiver Transceiver characteristic Min Typ Max Maximum transmit power Minimum transmit power 5 6.5 -17 8 Transmit power stability over the temperature range dB 1 -90 -91 -86 -83 -84 -80 dBm dBm +/- 0.5 Transmit power variation within the BT band RT -40C Sensitivity DH1 +85C RT -40C Sensitivity 3DH5 +85C Unit dB dBm dBm dBm dBm dBm dBm Table 9: Transceiver characteristics Table 10: Power control of WT32i Silicon Labs Page 16 of 63 Band / Frequency Standard Min (AVG / PEAK) Unit 54 / 74 dBuV/m 54 / 74 dBuV/m Band edge 2390MHz 54 / 74 dBuV/m Band edge 2483.5MHz 54 / 74 dBuV/m Band edge 2400MHz (conducted) -20 dBc Band edge 2483.5MHz (conducted) -20 dBc Band edge 2400MHz -30 dBm 3rd harmonic ETSI EN 300 328 transmitter spurious emissions ETSI EN 300 328 receiver spurious emissions Max (AVG / PEAK) Limit by the Standard (AVG / PEAK) 2nd harmonic FCC part 15 transmitter spurious emissions Typ (AVG / PEAK) 50 / 61 < 40 / 50 2nd harmonic -35 -30 dBm 3rd harmonic (2400 - 2479) MHz <-40 -30 dBm -47 dBm -47 dBm (1600 - 1653) MHz Table 11: WT32i-A spurious emissions Note: All the emissions tested with maximum 8 dBm TX power 5.5.2 Antenna Characteristics Note: Antenna characteristics may vary depending on the mother board layout. Following characteristics have been measured using DKWT32i * Antenna efficiency -3.5 dB (45%) * Peak gain 0 dBi Silicon Labs Page 17 of 63 0 dB -5 dB -10 dB -15 dB -20 dB Figure 5: Top view radiation pattern of DKWT32i -2 dB -4 dB -6 dB -8 dB -10 dB -12 dB -14 dB Figure 6: Side view radiation pattern of DKWT32i Silicon Labs Page 18 of 63 -1 dB -2 dB -3 dB -4 dB -5 dB -6 dB -7 dB -8 dB -9 dB -10 dB -11 dB -12 dB Figure 7: Front view radiation pattern Silicon Labs Page 19 of 63 5.6 Current Consumption Operation Mode Idle Sleep Connected, Sniff disabled Connected + Sniff, Master Connected + Sniff, Master Connected + Sniff, Slave Connected + Sniff, Slave A2DP Audio Streaming A2DP Audio Streaming Peak SET BT PAGEMODE 0 2000 0 SET BT PAGEMODE 0 2000 1 SET BT PAGEMODE 0 2000 2 SET BT PAGEMODE 1 2000 0 SET BT PAGEMODE 1 2000 1 SET BT PAGEMODE 1 2000 2 SET BT PAGEMODE 2 2000 0 SET BT PAGEMODE 2 2000 1 SET BT PAGEMODE 2 2000 2 SET BT PAGEMODE 3 2000 0 SET BT PAGEMODE 3 2000 1 SET BT PAGEMODE 3 2000 2 SET BT PAGEMODE 4 2000 0 SET BT PAGEMODE 4 2000 1 SET BT PAGEMODE 4 2000 2 SET BT PAGEMODE 0 2000 0 SET BT PAGEMODE 0 2000 1 SET BT PAGEMODE 0 2000 2 SET BT PAGEMODE 1 2000 0 SET BT PAGEMODE 1 2000 1 SET BT PAGEMODE 1 2000 2 SET BT PAGEMODE 2 2000 0 SET BT PAGEMODE 2 2000 1 SET BT PAGEMODE 2 2000 2 SET BT PAGEMODE 3 2000 0 SET BT PAGEMODE 3 2000 1 SET BT PAGEMODE 3 2000 2 SET BT PAGEMODE 4 2000 0 SET BT PAGEMODE 4 2000 1 SET BT PAGEMODE 4 2000 2 SET BT SNIFF 0 20 1 8 SET BT SNIFF 40 20 1 8 SET BT SNIFF 1000 20 1 8 SET BT SNIFF 40 20 1 8 SET BT SNIFF 1000 20 1 8 A2DP SINK, INTERNAL CODEC A2DP SOURCE, INTERNAL CODEC 12 32 12 32 75 70 Average 2.0 2.0 2.0 2.0 2.1 2.1 23 2.2 2.1 23 2.3 2.2 23 2.3 2.2 0.08 0.08 0.08 0.18 0.18 0.18 23.5 0.31 0.19 23 0.4 0.29 23 0.4 0.29 4.7 3.9 2.5 3.6 2.5 28 23 Unit mA mA mA Table 12: Current consumption of WT32i Silicon Labs Page 20 of 63 6 Power Control and Regulation WT32i contains an internal battery charger and a switch mode regulator that is mainly used for internal blocks of the module. The module can be powered from a single 3.3 V supply provided that VDD_CHG is floating. Alternatively the module can be powered from a battery connected to VDD_BAT and using an external regulator for VDD_IO. 1.8 V to 3.3 V supply voltage for VDD_IO can be used to give desired signal levels for the digital interfaces of the module. USB, however, requires 3.3 V for proper operation and thus, when USB is in use, 3.3 V for VDD_IO is required. VDD_CHG In Battery Charger Out VDD_BAT VREG_ENA Switch mode 1.8V regulator Linear 1.5V regulator AIO RF Core Audio Flash PIO USB UART PCM VDD_IO Figure 8: Power supply configuration of WT32i VDD_ENA is software configurable enable pin for the internal regulators. Using iWRAP the enable pin can be configured to 1. Latch on the internal regulators at the rising edge 2. Turn the regulators on at rising edge and turn off the regulators at falling edge 3. Latch the regulators on at the rising edge and turn off the regulators at the following rising edge GPIO can be configured to control an external regulator. Silicon Labs Page 21 of 63 Battery Voltage (2.7V...4.4V) VDD_BAT ON/OFF Button VREG_ENA IN R1 LDO (1.8V...3.6V) EN VDD_IO 100k C1 4u7 R2 GPIO (holds the external LDO on) 100k Figure 9: Example of making a power on/off button using the latch feature of the internal regulators iWRAP Example: Creating an on/off button with PIO2 holding the external regulator on "SET CONTROL VREGEN 2 4" (PIO is defined with a bit mask. 4 in hexadecimal is 100 in binary corresponding to PIO2) NOTE: With the configuration shown above, when doing a SW reset for the module C1 will hold the enable pin of the external regulator high until iWRAP has booted. This will prevent the module from turning off during reset. When resetting through the reset pin one has to make sure that the enable pin is held high as long as the reset pin is held active. Figure 10 shows an example how to arrange power control when on/off button is not implemented. VREG_ENA pin must not be connected to VDD_IO because leakage from VDD_BAT to VDD_IO will prevent VREG_ENA to fall low enough to turn off the internal regulators. Silicon Labs Page 22 of 63 Battery Voltage (2.7V...4.4V) VDD_BAT VREG_ENA On/Off cntrl IN LDO EN (1.8V...3.6V) VDD_IO Battery Voltage (2.7V...4.4V) VDD_BAT VREG_ENA On/Off cntrl IN LDO (1.8V...3.6V) EN VDD_IO Figure 10: Correct and wrong connection for the power on/off control 6.1 Protecting the Battery by Configuring the Module to Turn Off at Certain Voltage It is important not to let the battery be drained to voltages below 2.8V. In iWRAP it is possible to define certain level when the module turns off the regulators. iWRAP Example: Configure WT32i to start sending low battery warning at 3.4V, turn off at 3.3V and cease the low battery warning at 4.0V. Set PIO0 to indicate low batter "SET CONTROL BATTERY 3400 3300 4000 10" Silicon Labs Page 23 of 63 6.2 Reset WT32i may be reset from several sources: reset pin, power on reset, a UART break character or through software configured watchdog timer. At reset, the digital I/O pins are set to inputs for bi-directional pins and outputs are tri-state. The chip status after a reset is as follows: * * Warm Reset: data rate and RAM data remain available Cold Reset: data rate and RAM data are not available Table 13 shows the pin states of WT32i on reset. Pull-up (PU) and pull-down (PD) default to weak values unless specified otherwise. NOTE: In order to make reset work properly VREG_ENA pin (1st pin of WT32i module) has to be driven high for the time of reset. Pin Name / Group I/O Type No Core Voltage Reset Full Chip Reset USB UART_RX UART_CTS UART_TX UART_RTS SPI_MOSI SPI_CLK Digital bi-directional N/A N/A Digital input with PD PD PD Digital output with PU PU PU PD PD PU PU PD PD PD PD SPI_MISO SPI_CS PCM_IN PCM_CLK PCM_SYNC PCM_OUT GPIO Digital input with PD Digital tristate output with PD Digital input with PU Digital input with PD Digital bi-directional with PD Digital tri-state output with PD Digital bi-directional with PU/PD Table 13: Pin states on reset 6.2.1 Internal POR WT32i has two internal POR circuits. One is internally to the BC5 chip. In BC5 the power on reset occurs when the core supply voltage (output of the internal 1.5V regulator) falls below typically 1.26V and is released when VDD_CORE rises above typically 1.31V. Another POR circuit is embedded to the module and it keeps the module in reset until supply voltages have stabilized. This is to prevent corruption of the internal flash memory during boot. The embedded POR is shown in the figure Figure 2Figure 11. Because the POR is based on a simple RC time constant it will not work if the supply voltage ramps very slowly or if the reset pin is not connected to high impedance. It is recommended that the power ramp will not take more than 10 msec. If the reset pin is connected to a host it is good to place a diode between the host and the module as shown in Figure 12. A diode will prevent the host from pulling the reset low before the internal flash has its supply stabilized. Silicon Labs Page 24 of 63 WT32i Reset BC05 22nF BC05 R1 Reset 220k Figure 11: Embedded POR of WT32i Host CPU WT32i Reset GPIO Figure 12: An example how to connect CPU GPIO to the reset pin of the module Silicon Labs Page 25 of 63 7 Battery Charger The battery charger is a constant current / constant voltage charger circuit, and is suitable for lithium ion/polymer batteries only. It shares a connection to the battery terminal, VDD_BAT, with the switch-mode regulator. The charger is initially calibrated by Bluegiga Technologies to have Vfloat = 4.15V - 4.2 V. The constant current level can be varied to allow charging of different capacity batteries. WT32i allows a number of different currents to be used in the battery charger hardware. Values written to PS key 0x039b CHARGER_CURRENT in the range 1..15 specify the charger current from 40..135mA in even steps. Values outside the valid 0..15 range result in no change to the charging current. The default charging current (Key = 0) is nominally 40mA. Setting 0 is interpreted as "no-change" so it will be ignored The charger enters various states of operation as it charges a battery. These are shown below: * * * * * Off: entered when the charger is disconnected. Trickle Charge: entered when the battery voltage is below 2.9V. Fast Charge - Constant Current: entered when the battery voltage is above 2.9V. Fast Charge - Constant Voltage: entered when the battery has reached V float, the charger switches mode to maintain the cell voltage at V float voltage by adjusting the constant charge current. Standby: this is the state when the battery is fully charged and no charging takes place. When a voltage is applied to the charger input terminal VDD_CHG, and the battery is not fully charged, the charger will operate and a LED connected to the terminal LED0 will illuminate. By default, until the firmware is running, the LED will pulse at a low-duty cycle to minimize current consumption. The battery charger circuitry auto-detects the presence of a power source, allowing the firmware to detect when the charger is powered. Therefore, when the charger supply is not connected to VDD_CHG, the terminal must be left open circuit. The VDD_CHG pin, when not connected, must be allowed to float and not be pulled to a power rail. When the battery charger is not enabled, this pin may float to a low undefined voltage. Any DC connection will increase current consumption of the device. Capacitive components such as diodes, FETs, and ESD protection, may be connected. The battery charger is designed to operate with a permanently connected battery. If the application permits the charger input to be connected while the battery is disconnected, the VDD_BAT pin voltage may become unstable. This, in turn, may cause damage to the internal switch-mode regulator. Connecting a 470F capacitor to VDD_BAT limits these oscillations thus preventing damage. WARNING: Use good consideration for battery safety. Do not charge with too much current. Do not charge when the temperature is above 60C or below 0C. WT32i is initially calibrated to stop charging when battery voltage is at 4.2 V. Do not try to charge batteries above 4.2 V. Do not short circuit the battery or discharge below 1.5 V. Silicon Labs Page 26 of 63 8 GPIO and AIO Functions 8.1 iWRAP supported GPIO Functions Various GPIO functions are supported by iWRAP. These include: * Setting each GPIO state individually * Binding certain iWRAP commands to GPIO to trigger the command at either the rising or falling edge of the GPIO * Carrier detect signal to indicate an active Bluetooth connection * Implementing RS232 modem signals * iWRAP ready indicator to signal to a host that iWRAP is ready to use * UART bypass mode to route UART signals to GPIO pins instead of iWRAP * Driving low frequency pulsed signal from a GPIO Some of the functions are FW dependent. Refer to latest iWRAP user manual for the detailed information about the GPIO functions. 8.2 Outputting Internal Clocks Internal clocks can be routed to either AIO0 or AIO1 by setting PS Keys. To route internal clock to AIO0 set PSKEY_AMUX_AIO0 to 0x00fe. Following table shows how to set the PSKEY_AMUX_CLOCK to get certain frequency from AIO0. AMUX_CLOCK Freq (MHz) @ AIO0 0x0014 0x0004 0x0013 0x0017 0x0003 0x0016 0x0007 0x0011 0x0006 0x0002 0x0009 0x0005 1 2 3 4 6 6.5 8 12 13 16 24 32 Table 14: Selectable internal clock frequencies from AIO0 iWRAP does not support this feature. To use this feature either the particular PS Keys must be set to each module separately or then ask for custom FW from Bluegiga. Silicon Labs Page 27 of 63 8.3 Auxiliary ADC Simple iWRAP command can be used to read the ADC output from either of the two AIO pins. Refer to latest iWRAP user manual for the detailed information. 8.4 Software I2C Interface PIO6 and PIO7 can be used to form a master IC interface. The interface is formed using software to drive these lines. Therefore it is suited only to relatively slow functions such as driving a dot matrix LCD, keyboard scanner or configuring external audio codec. I2C interface requires a custom FW. PIO I2C Signal PIO6 PIO7 SCL SDA Table 15: I2C Interface of WT32i Silicon Labs Page 28 of 63 9 Serial Interfaces 9.1 UART Interface WT32i has a standard UART serial interface that provides a simple mechanism for communicating with other serial devices using the RS232 protocol. UART configuration parameters, such as baud rate, parity and stop bits can be configured with an iWRAP command. The hardware flow control is enabled by default. HW flow control can be disabled in HW by connecting UART_NCTS to GND and leaving UART_NRTS floating. Parameter Possible Values Minimum Baud rate 1200 baud (2%Error) 9600 (1%Error) 4Mbaud (1%Error) RTS/CTS or None None, Odd, Even 1 or 2 8 Maximum Flow control Parity Number of stop bits Bits per byte Table 16: Possible UART settings iWRAP Example: Configuring local UART to 9600bps, 8 data bits, no parity and 1 stop bit SET CONTROL BAUD 9600, 8N1 (9600 = baud rate, N = No parity, 1 = 1 stop bit) Baud Rate Error 1200 2400 4800 9600 19200 38400 57600 76800 115200 230400 460800 921600 1382400 1843200 2764800 3686400 1.73% 1.73% 1.73% -0.82% 0.45% -0.18% 0.03% 0.14% 0.03% 0.03% -0.02% 0.00% -0.01% 0.00% 0.00% 0.00% Table 17: Standard Baud Rates Silicon Labs Page 29 of 63 9.1.1 Resetting Through UART Break Signal The UART interface can reset WT32i on reception of a break signal. A break is identified by a continuous logic low (0V) on the UART_RX terminal. If tBRK is longer than the value (in microseconds), defined by PSKEY_HOSTIO_UART_RESET_TIMEOUT, (0x1a4), a reset occurs. Values below 1000 are treated as zero and values above 255000 are truncated to 255000. This feature allows a host to initialise the system to a known state. Also, WT32i can emit a break character that may be used to wake the host. Default PSKEY_HOSTIO_UART_RESET_TIMEOUT setting in WT32i is zero, which means that this feature is disabled. To use this feature, either the PS setting has to be changed for each module separately or ask for modules with custom FW with appropriate settings. 9.1.2 UART Configuration While Reset is Active The UART interface for WT32i is tristate while the chip is being held in reset. This allows the user to daisy chain devices onto the physical UART bus. The constraint on this method is that any devices connected to this bus must tristate when WT32i reset is de-asserted and the firmware begins to run. 9.1.3 UART Bypass Mode Alternatively, for devices that do not tristate the UART bus, the UART bypass mode on WT32i can be used. The default state of WT32i after reset is de-asserted; this is for the host UART bus to be connected to the WT32i UART, thereby allowing communication to WT32i via the UART. All UART bypass mode connections are implemented using CMOS technology and have signalling levels of 0V and VDD_IO. The bypass mode is enabled with a simple iWRAP command. When in bypass mode, the module is automatically set into deep sleep state indefinitely. Physical reset is required to return to normal operation mode. The current consumption of a module in bypass mode is equal to a module in standby (idle) mode. It is important for the host to ensure a clean Bluetooth disconnection of any active links before the bypass mode is invoked. Therefore, it is not possible to have active Bluetooth links while operating the bypass mode. RESET RXD Host CTS processor RTS TXD Test interface UART_TX PIO4 UART_RTS PIO5 UART_CTS PIO6 UART_RX PIO7 TX RTS Another device CTS RX UART WT32i WTxx WT12 Figure 13: UART bypass architecture Silicon Labs Page 30 of 63 9.2 USB Interface WT32i has a full-speed (12Mbps) USB interface for communicating with other compatible digital devices. The USB interface on WT32i acts as an USB peripheral, responding to requests from a master host controller. WT32i can be used as bus-powered or self-powered device. See the WT_USB_Design_Guide available in the Bluegiga techforum for details about the SW and HW configuration of the USB interface. WT32i VDD_IO VDD_IO VDD_BAT Figure 14: Bus-powered WT32i device configuration Silicon Labs Page 31 of 63 WT32i VDD_IO VDD_IO Figure 15: Self powered WT32i device configuration 9.3 Programming and Debug Interface (SPI) The synchronous serial port interface (SPI) is for interfacing with other digital devices. The SPI port can be used for system debugging. It can also be used for programming the Flash memory. SPI interface is connected by using the MOSI, MISO, CSB and CLK pins. SPI interface cannot be used for any application purposes. 9.3.1 Multi-slave Operation WT32i should not be connected in a multi-slave arrangement by simple parallel connection of slave MISO lines. When WT32i is deselected (SPI_CS# = 1), the SPI_MISO line does not float. Instead, WT32i outputs 0 if the processor is running or 1 if it is stopped. Silicon Labs Page 32 of 63 10 Audio Interfaces 10.1 Stereo Audio Codec Interface Stereo audio CODEC operates from an internal 1.5V power supply. It uses fully differential architecture in analog signal path for the best possible common mode noise rejection while effectively doubling the signal amplitude. The stereo audio bus standard I2S is supported and a software I2C interface can be implemented using GPIOs to configure an external audio CODEC. Figure 16: Stereo CODEC input and output stages 10.1.1 ADC The ADC consists of two second-order sigma-delta converters and gain stages. The gain stage consists of digital and analog gain stages which are controlled by iWRAP. The optimal combination of digital and analog gain is automatically selected by iWRAP. The analog gain stage consist selectable 24 dB preamplifier for selecting microphone or line input levels and an amplifier which can be configured in 3 dB steps. The iWRAP gain selection values are shown in the Table 19. Following sample rates are supported * * * * * * * 8kHz 11.025kHz 16kHz 22.05kHz 24kHz 32kHz 44.1kHz Silicon Labs Page 33 of 63 Preamp ON = 24 dB gain (MIC input) Preamp OFF = 0 dB gain (line input) iWRAP Gain Setting (-27...39)dB Table 18: ADC amplifier block diagram Gain Setting In iWRAP 0 1 2 3 4 5 6 7 8 9 A B C D E F 10 11 12 13 14 15 16 ADC Gain (dB) Preamp OFF (Line input mode) -27 -24 -21 -18 -15 -12 -9 -6 -3 0 3 6 9 12 15 18 21 24 27 30 33 36 39 ADC GAIN (dB) Preamp ON (MIC input mode) -3 0 3 6 9 12 15 18 21 24 27 30 33 36 39 42 45 48 51 54 57 60 63 Table 19: ADC Gain Selection In iWRAP iWRAP Example: Setting line input with 0 dB gain "SET CONTROL PREAMP 0" "SET CONTROL GAIN 9 x" (x is the DAC gain) Silicon Labs Page 34 of 63 10.1.2 DAC The DAC consists of two second-order sigma-delta converters and gain stages. The gain stage consists of digital and analog gain stages which are controlled by iWRAP. The optimal combination of digital and analog gain is automatically selected by iWRAP. The analog gain stage consist selectable 24 dB preamplifier for selecting microphone or line input levels and an amplifier which can be configured in 3 dB steps. The iWRAP gain selection values are shown in Table 20. Following sample rates are supported * * * * * * * * 8kHz 11.025kHz 16kHz 22.05kHz 24kHz 32kHz 44.1kHz 48kHz Gain Setting In iWRAP DAC Gain (dB) 0 1 2 3 4 5 6 7 8 9 A B C D E F 10 11 12 13 14 15 16 -42 -39 -36 -33 -30 -27 -24 -21 -18 -15 -12 -9 -6 -3 0 3 6 9 12 15 18 21 24 Table 20: DAC gain selection in iWRAP iWRAP Example: Setting output with 0 dB gain "SET CONTROL GAIN x E" (x is the ADC gain) Silicon Labs Page 35 of 63 10.1.3 Microphone Input Figure 17 shows the recommended microphone biasing. The microphone bias, MIC_BIAS, derives its power from the VDD_BAT and requires 1uF capacitor on its output (C1). The input impedance at AUDIO_IN_P_LEFT and AUDIO_IN_N_LEFT is typically 6kohm and C5 and C4 are typically 1uF. If bass roll-off is required to limit the wind noise on the microphone then C4 and C5 should be 150 nF. R2 sets the microphone load impedance and is normally in the range of 1k to 2k R1, C2 and C3 improve the supply rejection by decoupling supply noise from the microphone. Values should be selected as required. R1 can be connected or to the MIC_BIAS output (which is ground referenced and provides good rejection of the supply) as shown in Figure 17. MIC_BIAS is configured to provide bias only when the microphone is required. R1 may also be connected to a convenient supply, in which case the bias network is permanently enabled. MIC_BIAS WT32i C1 R1 AUDIO_IN_P_LEFT C5 C2 R2 AUDIO_IN_N_LEFT C4 C3 MIC Figure 17: Microphone connection to audio input The MIC_BIAS is like any voltage regulator and requires a minimum load to maintain regulation. The MIC_BIAS maintains regulation within the limits 0.200mA to 1.230mA. If the microphone sits below these limits, then the microphone output must be pre-loaded with a large value resistor to ground. The audio input is intended for use in the range from 1A @ 94dB SPL to about 10A @ 94dB SPL. With biasing resistors R1 and R2 equal to 1k, this requires microphones with sensitivity between about -40dBV and -60dBV. Table 21 lists the possible voltage and current setting in iWRAP for the MIC_BIAS. Setting in iWRAP Voltage (V) Current (mA) 0 1 2 3 4 5 1.71 1.76 1.82 1.87 1.95 2.02 0.200 0.280 0.340 0.420 0.480 0.530 Silicon Labs Page 36 of 63 6 7 8 9 A B C D E F 0.610 0.670 0.750 0.810 0.860 0.950 1.000 1.090 1.140 1.230 2.10 2.18 2.32 2.43 2.56 2.69 2.90 3.08 3.33 3.57 Table 21: MIC_BIAS settings in iWRAP 10.1.4 Line Input Line input mode is selected by setting the ADC preamplifier off (see chapter 10.1.1). In the line input mode the input impedance varies from 6k to 30 kohm depending on the gain setting. Figure 18 and Figure 19 show examples of line input connection with WT32i. The maximum line level rms voltage can vary from 0.3 up to 1.6 Vrms depending on the application, while the maximum for WT32i is 0.4Vrms (0.8Vrms differential). Thus it may be necessary to use a voltage divider (R1 and R2) at the input to attenuate the incoming signal. C1 and C2 are typically 1uF ceramic X7R or film type capacitors. It is a good practice to place a LC (22nH + 15pF) filter close to each input to filter out any RF noise that might couple to the audio traces. WT32i Line input C1 R1 AUDIO_IN_P_LEFT R2 C2 AUDIO_IN_N_LEFT Figure 18: Single ended line input example Silicon Labs Page 37 of 63 WT32i Line input P C1 R1 AUDIO_IN_P_LEFT R2 Line input N C2 AUDIO_IN_N_LEFT Figure 19: Differential line input example 10.1.5 Output Stage The output stage digital circuitry converts the signal from 16-bit per sample, linear PCM of variable sampling frequency to bit stream, which is fed into the analogue output circuitry. The output stage circuit comprises a DAC with gain setting and class AB output stage amplifier. The output is available as a differential signal between AUDIO_OUT_N_LEFT and AUDIO_OUT_P_LEFT for left channel and AUDIO_OUT_N_RIGHT and AUDIO_OUT_P_RIGHT for right channel. The output stage is capable of driving a speaker directly when its impedance is at least 16. Figure 20 show an example of differentially connected speaker and Figure 21 show an example of speaker connected single-ended. Differential (balanced) connection provides perfect common mode rejection ratio with effectively 3 dB higher amplitude so it is recommended to use differential signaling always when possible. Silicon Labs Page 38 of 63 WT32i AUDIO_OUT_P_LEFT AUDIO_OUT_N_LEFT Figure 20: Differentially connected speaker WT32i AUDIO_OUT_P_LEFT C1 AUDIO_OUT_N_LEFT Figure 21: Single-ended speaker connection Silicon Labs Page 39 of 63 10.1.6 Mono Operation Mono operation is a single-channel operation of the stereo codec. The left channel represents the single mono channel for audio in and audio out. In mono operation the right channel is the auxiliary mono channel that may be used in dual mono channel operation. Dual mono feature is FW dependent and iWRAP does not generally support it. 10.1.7 Side Tone In some applications it is necessary to implement side tone. This involves feeding an attenuated version of the microphone signal to the earpiece. The WT32i codec contains side tone circuitry to do this. There is no iWRAP support for the side tone but the side tone is configurable through PS Keys. To implement a side tone, either the PS setting has to be programmed for each module separately or ask for modules with custom FW with appropriate settings. The side tone hardware is configured through the following PS Keys: * PSKEY_SIDE_TONE_ENABLE * PSKEY_SIDE_TONE_GAIN * PSKEY_SIDE_TONE_AFTER_ADC * PSKEY_SIDE_TONE_AFTER_DAC 10.2 PCM Interface The audio PCM interface supports continuous transmission and reception of PCM encoded audio data over Bluetooth. PCM is a standard method used to digitise audio, particularly voice, for transmission over digital communication channels. Through its PCM interface, WT32i has hardware support for continual transmission and reception of PCM data, so reducing processor overhead. WT32i offers a bidirectional digital audio interface that routes directly into the baseband layer of the on-chip firmware. It does not pass through the HCI protocol layer. Hardware on WT32i allows the data to be sent to and received from a SCO connection. Using HCI FW up to 3 SCO connections can be supported by the PCM interface at any one time. However iWRAP supports only 1 SCO connection at a time. WT32i can operate as the PCM interface master generating PCM_SYNC and PCM_CLK or as a PCM interface slave accepting externally generated PCM_SYNC and PCM_CLK. WT32i is compatible with various clock formats, including Long Frame Sync, Short Frame Sync and GCI timing environments. WT32i supports 13-bit or 16-bit linear, 8-bit -law or A-law companded sample formats, and can receive and transmit on any selection of 3 of the first four slots following PCM_SYNC. The PCM configuration options are enabled by setting the PS Key PSKEY_PCM_CONFIG32. Please contact Bluegiga technical support for details about the PCM configuration. 10.3 I2S Interface The digital audio interface supports the industry standard formats for I 2S, left-justified or righ justified. The interface shares the same pins as the PCM interface, which means each audio bus is mutually exclusive in its usage. The internal representation of audio samples within WT32i is 16-bit and data on SD_OUT is limited to 16-bit per channel. WT32i is not capable of generating the master clock for I2S, so when configured as a master, it can only be used with a codec that is capable of producing the master clock from the SCK. Silicon Labs Page 40 of 63 I2S CODEC MCLK Generator ASI SCK WS WT32i I2S_IN I2S_OUT Figure 22: I2S scheme for WT32i Bit Mask Name D[0] 0x0001 CONFIG_JUSTIFY_FORMAT Description 0 for left justified, 1 for right justified. D[1] 0x0002 CONFIG_LEFT_JUSTIFY_DELAY For left justified formats: 0 is MSB of SD data occurs in the first SCLK period following WS transition. 1 is MSB of SD data occurs in the second SCLK period. D[2] 0x0004 CONFIG_CHANNEL_POLARITY For 0, SD data is left channel when WS is high. For 1 SD data is right channel. D[3] 0x0008 CONFIG_AUDIO_ATTEN_EN D[7:4] 0x00F0 CONFIG_AUDIO_ATTEN For 0, 17-bit SD data is rounded down to 16bits. For 1, the audio attenuation defined in CONFIG_AUDIO_ATTEN is applied over 24bits with saturated rounding. Requires CONFIG_16_BIT_CROP_EN to be 0. Attenuation in 6dB steps. D[9:8] 0x0300 CONFIG_JUSTIFY_RESOLUTION Resolution of data on SD_IN, 00=16bit, 01=20bit, 10=24bit, 11=Reserved. This is required for right justified format and with left justified LSB first. D[10] 0x0400 CONFIG_16_BIT_CROP_EN For 0, 17-bit SD_IN data is rounded down to 16bits. For 1 only the most significant 16bits of data are received. Table 22: PSKEY_DIGITAL_AUDIO_CONFIG Silicon Labs Page 41 of 63 Figure 23: Digital Audio Interface Modes 10.4 IEC 60958 Interface The IEC 60958 interface is a digital audio interface that uses bi-phase coding to minimize the DC content of the transmitted signal and allows the receiver to decode the clock information from the transmitted signal. The IEC 60958 specification is based on the 2 industry standards: * AES/EBU * Sony and Philips interface specification SPDIF The interface is compatible with IEC 60958-1, IEC 60958-3 and IEC 60958-4. The SPDIF interface signals are SPDIF_IN and SPDIF_OUT and are shared no the PCM interface pins. The input and output stages of the SPDIF pins can interface to: * 75 coaxial cable with an RCA connector, see Figure 24 * An optical link that uses Toslink optical components Silicon Labs Page 42 of 63 DC bias for the comparator input R14 1uF/6.3V/X5R/10% 0.15uF/10V/X5R C6 5 SPDIF_IN V+ U3 2 C2 - 6 4 1 + SHTDN 3 V- 1uF/6.3V/X5R/10% C4 R12 Impedance matching to 75 ohm R15 10K, 50V, 0.063W R13 10K, 50V, 0.063W 1.0K, 50V, 0.063W C5 0.15uF/10V/X5R C7 1.0K, 50V, 0.063W 3V3 R11 3V3 D1 13 470K, 50V, 0.063W 10000pF/25V/X7R 2 150R, 50V, 0.063W R6 R5 150R, 50V, 0.063W C OMPAR ATOR _TLV3501AID BVT Comparator (Tpd max 10ns) ESD_PROTEC TION U1-C R1 5 6 560R, 50V, 0.063W DC block 74HC14D 2 3V3 U1-B 1 U1-D R2 ESD_PROTECTION 3 4 13 9 8 SPDIF_OUT 560R, 50V, 0.063W 74HC14D D2 R16 2 74HC14D U1-A C1 R3 2 100K, 50V, 0.063W J2 RC A_R ED 1 2 560R, 50V, 0.063W 0.15uF/10V/X5R 74HC14D J1 R4 RC A_R ED 120R, 50V, 0.063W 1 Buffering required to drive 75 ohm load Impedance matching to 75 ohm Figure 24: Example circuit for SPDIF interface (co-axial) Silicon Labs Page 43 of 63 11 Design Guidelines This chapter shows briefly the most important points to consider when making a design with WT32i. Please refer to the DKWT32i datasheet for detailed description of the development board design. 11.1 Audio Layout Guide EMC Considerations Typical RF noise with Bluetooth 11.1.1 To avoid RF noise coupling top the audio traces it is extremely important to make sure that there aren't GND loops in the audio traces. Audio layout can not be compromised. RF noise that couples to audio signal lines * How the BT noise couples to audio? usually demodulates down to audio band causing very unpleasant whining noise. noiselines either through a parasitic capacitance or by coupling to a loop. The noise that Noise couples-1.6kHz to signals 1 Bluetoothtoslot couples to a loop is proportional the= 625us area of the loop and to the electromagnetic field flowing through the = 1.6kHz loop. Thus the noise can1 /be625e-6 minimized in two ways. Minimizing the field strength flowing through the loop by - 320Hz noise placing the signal lines far from the RF source or most importantly minimize the size of the loop by keeping 5 slot packet (A2DP profile) the trace as short as possible and making sure that the path for the return current (usually GND) is low 1 / (5 x 625e-6) = 320Hz (5) impedance and follows the forward current all the way as close as possible. GND vias must be placed right next to the any component GND pins solid GND region plane must follow the trace all the way from start to the * RF takes an amplifier outand from it's linear causing demodulation of RF end. When using fully differential they should be routed as differential pairs, parallel and symmetrically. (6) down to audio band.signals Noise couples through a parasitic capacitance EM field couples to a loop RL RL Figure 25: Noise coupling schemes 11.1.2 Choosing Capacitors and Resistors Metal film resistors have lower noise than carbon resistors which makes them more suitable for high quality audio. Non-linearity of capacitors within the audio path will have an impact on the audio quality at the frequencies where the impedance of the capacitors become dominant. At higher frequencies the amplitude is not determined by the value of the capacitors but at the lower frequencies the impact of the capacitors will be seen. Ceramic capacitors should be X5R or X7R type capacitors with relative high voltage rating. The higher the capacitance value, the lower is the frequency where the non-linearity will start to have an impact. Thus it is not a bad idea to select the capacitors value bigger than necessary from the frequency response point of view. For optimal audio quality the best selection is to use film capacitors. Film capacitors have excellent linearity and they are non-polarized which makes them perfect choice for using in audio path. The drawback of film capacitors is bigger physical size and higher cost. Figure 26 shows a modulation distortion measurement when using different type of capacitors in the audio paths. Modulation distortion measures the amount of distortion between two closely located sine waves. The Silicon Labs Page 44 of 63 difference between the different capacitors is obvious at low frequencies where the impedance of the capacitor is dominant. Figure 26: Modulation distortion with different type of capacitors 11.2 RF Layout Guide The chip antenna of WT32i requires only a small metal clearance area directly under the antenna. The antenna operation is dependent on the GND planes on both sides of the antenna. Minimum 15mm of GND plane must be placed on both sides of the module and the GND plane of the motherboard must reach under the edges of the module as shown in the Figure 27. Silicon Labs Page 45 of 63 Board edge Min 15mm Min 15mm 6mm Metal clearance area GND plane indentation 2mm GND plane indentation max 5.9 mm Figure 27: Recommended layout for WT32i Figure 28: Poor layouts for WT32i Use good layout practices to avoid excessive noise coupling to supply voltage traces or sensitive analog signal traces. If using overlapping ground planes use stitching vias separated by max 3 mm to avoid emission from the edges of the PCB. Connect all the GND pins directly to a solid GND plane and make sure that there is a low impedance path for the return current following the signal and supply traces all the way from start to the end. Silicon Labs Page 46 of 63 - Place MIC biasing resistors symmetrically as close to microhone as pos - Make sure that the bias trace does not cross separated GND regions (D AGND) so that the path for the return current is cut. If this is not possibl not separate GND regions but keep one solid GND plane. -A good Keep the trace as short as possible practice is to dedicate one of the inner layers to a solid GND plane and one of the inner layers to supply voltage planes and traces and route all the signals on top and bottom layers of the PCB. This arrangement will make sure that any return current follows the forward current as close as possible and any loops are minimized. Recommended PCB layer configuration Signals GND Power Signals Figure 29: Typical 4-layer PCB construction Overlapping GND layers without GND stitching vias Overlapping GND layers with GND stitching vias shielding the RF energy Figure 30: Use of stitching vias to avoid emissions from the edges of the PCB Silicon Labs Page 47 of 63 11.3 Example Application Schematics Figure 31: Example schematic with on/off button, silicon microphone and stereo speakers Silicon Labs Page 48 of 63 NOTE: Differential audio provides excellent com m on m ode rejection and effectively douples the am plitude. Thus it is s trongly recom m endable to us e differential ins tead of s ingle ended when ever pos s ible C26 2TIP 330uF/6.3V/20%/TAN/ESR<10mohm C28 U2 TPS79933 EN OUT NR 5 4 2 R11 1 C22 15pF C20 1uF/X7R R12 R17 1 2 1 2 L4 15nH 2.2K, 50V, 0.063W C21 1uF/X7R 7.5K, 50V, 0.063W R15 1 L3 15nH 2 TIP 3 RING 1 SLEEVE 2 7.5K, 50V, 0.063W C19 15pF J3 SJ-3523-SMT-TR 18 19 20 21 22 23 24 25 26 27 28 29 30 2.2uF C11 2.2uF C13 2 3 IN GND 1 2 2.2K, 50V, 0.063W C25 1uF/X7R 1uF 3V3 GND GND GND AIO0 AIO1 PIO0 PIO1 PIO2 PIO3 USB_DN USB_DP PIO9 PIO10 RXD TXD 3V3 SLEEVE 1M, 50V, 0.1W, 5% R3 R16 1 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 C18 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 GND RESET RTS CTS PIO8 PIO7 PIO6 PIO5 PIO4 PCM_IN PCM_OUT PCM_SYNC PCM_CLK ON/OFF_CNTRL_FROM_HOST AUDIO_OUT_P_LEFT AUDIO_OUT_N_LEFT AGND AUDIO_OUT_P_RIGHT AUDIO_OUT_N_RIGHT AUDIO_IN_N_LEFT AUDIO_IN_P_LEFT AGND AUDIO_IN_N_RIGHT AUDIO_IN_P_RIGH MIC_BIAS GND VDD_CHG VDD_BAT LED0 SPI_MOSI SPI_MISO SPI_CLK SPI_CS GND 1 C24 1uF/X7R 1M, 50V, 0.1W, 5% 2 5V0 WT32I RING 1 J2 SJ-3523-SMT-TR 330uF/6.3V/20%/TAN/ESR<10mohm MOD4 3 3V3 J1 1 2 3 4 5 6 MISO 3V3 CLK MOSI CSB GND Line level input can be as high as 4.37 Vpp. Voltage divider is us ed to drop this down to below 1 Vpp to avoid s aturation of WT32 input D1 RESET_FROM_HOST During boot the diode will prevent the hos t pulling res et low before the internal flas h has its s upply voltage s tabilis ed Figure 32: Example schematic with single ended line input, single ended output and with on/off control from a host Silicon Labs Page 49 of 63 Figure 33: Example schematic for connecting external audio PA to the stereo audio output Silicon Labs Page 50 of 63 3V 3 MOD1 W T 32I 5 VDD RST VSS 4 MR RST 1 50 A UDIO_OUT _P _LEFT 49 AUDIO_OUT _N_LEFT 48 A GND 47 AUDIO_OUT _P _RIGHT 46 AUDIO_OUT _N_RIGHT 45 AUDIO_IN_N_LE FT 44 AUDIO_IN_P _LE FT 43 A GND 42 A UDIO_IN_N_RIGHT 41 A UDIO_IN_P _RIGH 40 MIC_BIAS 39 GND 38 VDD_CHG 37 VDD_BA T 36 LE D0 35 S P I_MOS I 34 S P I_MIS O 33 S PI_CLK 32 S P I_CS 31 GND 3V3 3V3 J7 1 2 3 4 5 6 18 19 20 21 22 23 24 25 26 27 28 29 30 R37 5.1K, 50V, 0.063W, +/-5% 3V 3 GND GND GND A IO0 A IO1 P IO0 P IO1 P IO2 P IO3 US B_DN US B_DP P IO9 P IO10 RX D T XD 3V3 GND RESET RTS CTS PIO8 PIO7 PIO6 PIO5 PIO4 PCM_IN PCM_OUT PCM_SYNC PCM_CLK 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 2 3 Debug header U10 MCP1319 PIO7/I2C_S DA B1 2 B2 3 P IO6/I2C_S CL I2S_SDIN I2S _S DOUT I2S_W S I2S_SCK 3V3 A1 A2 1 4 SW1 R38 4.7K , 50V , 0.063W , 5% R40 3V 3 AVSS_ADC AVSS_DAC DRVSS MIC1R/LINE1R LEFT_LOM LEFT_LOP RIGHT_LOM RIGHT_LOP GND GND GND GND 17 26 21 C32 1uF/6.3V/X5R/10% C31 0.1uF/10V/X5R/10% C30 10uF/6.3V/X5R/10% C29 1uF/6.3V/X5R/10% C28 C26 C25 33 34 35 36 2 TLV320AIC32 R65 C54 AP7313 IN 1 NP R67 1 RCA_RED 1M, 50V, 0.1W, 5% 2 U11 OUT U8 0.1uF/10V/X5R/10% C42 28 27 30 29 22 20 R49 19 U9 23 RCA_RED HPRCOM 1M, 50V, 0.1W , 5% 2 1 HPLCOM 1 U15 HPLOUT HPROUT 2 6 C43 DVSS 11 1uF/6.3V/X5R/10% MIC3R/LINE3R GND C35 1uF/16V/20% 32 MIC3L/LINE3L 3 16 1uF/6.3V/X5R/10% 1uF/16V/20% 1uF/6.3V/X5R/10% 14 R46 7 C24 DVDD C23 IOVDD MIC2R/LINE2R 0.1uF/10V/X5R/10% MIC2L/LINE2L 0.1uF/10V/X5R/10% 13 C36 1M, 50V , 0.1W , 5% 2 1 1uF/6.3V/X5R/10% 1 U18 RCA_WHITE 1uF/6.3V/X5R/10% 12 C22 MIC1L/LINE1L 2 C21 25 18 24 0.1uF/10V/X5R/10% 5 3 2 1 31 4 DIN DOUT WCLK BCLK MCLK AVDD_DAC DRVDD DRVDD MICBIAS 0.1uF/10V/X5R/10% 10 RESET 9 SCL 15 SDA 8 4.7K , 50V , 0.063W , 5% C33 330uF/6.3V /20%/T AN/E SR<10mohm C34 2 330uF/6.3V /20%/T A N/ES R<10mohm NP 0.1uF/10V/X5R/10% R64 R66 C53 U12 RCA_WHITE 1M, 50V, 0.1W, 5% 1 Figure 34: Example schematic with an external I2S codec Silicon Labs Page 51 of 63 12 Physical Dimensions FCC ID: QOQWT32I IC: 5123A-BGTWT32I KCC-CRM-BGT-WT32I 3.35 mm 15.0 (+/-0.1) mm 9.15 mm Model: WT32i-A Ant 3.8 mm R 209-JXXXXX 17.9 (+/-0.1) mm 23.9 (+/-0.2) mm 2.4 (+/-0.15) mm 5.6 (+/-0.2) mm 2.1 (+/-0.15) mm 15.9 (+/-0.2) mm 23.9 (+/-0.2) mm Figure 35: Physical dimensions of WT32i Silicon Labs Page 52 of 63 Figure 36: Pin dimensions of WT32i, top view Figure 37: Recommended PCB land pattern for WT32i Silicon Labs Page 53 of 63 13 Soldering Recommendations WT32i is compatible with industrial standard reflow profile for Pb-free solders. The reflow profile used is dependent on the thermal mass of the entire populated PCB, heat transfer efficiency of the oven and particular type of solder paste used. Consult the datasheet of particular solder paste for profile configurations. Bluegiga Technologies will give following recommendations for soldering the module to ensure reliable solder joint and operation of the module after soldering. Since the profile used is process and layout dependent, the optimum profile should be studied case by case. Thus following recommendation should be taken as a starting point guide. - Refer to technical documentations of particular solder paste for profile configurations - Avoid using more than one flow. - Reliability of the solder joint and self-alignment of the component are dependent on the solder volume. Minimum of 150m stencil thickness is recommended. - Aperture size of the stencil should be 1:1 with the pad size. - A low residue, "no clean" solder paste should be used due to low mounted height of the component. Figure 38: Reference reflow profile Silicon Labs Page 54 of 63 14 Package Figure 39: Carrier tape dimensions Silicon Labs Page 55 of 63 Figure 40: Reel dimensions Silicon Labs Page 56 of 63 15 Certification Guidance for an End Product Using WT32i 15.1 Bluetooth End Product Listing The Bluetooth SIG requires for every commercially available product implementing Bluetooth technology to be listed on the Bluetooth SIG End Product Listing (EPL). For the details on how to make the end product listing, please refer to the Bluetooth End Product Listing Guide available in www.bluegiga.com. 15.2 CE Approval of an End-Product When placing the CE logo to an end-product the manufacturer declares that the product is in conformity with the requirements of the R&TTE directive. The minimum requirements for placing the CE logo to an endproduct are * Declaration of Conformity signed by the manufacturer. The person who signs the DoC must be traceable * Generation of a technical construction file including o Technical information about the product o Test reports for all the relevant standards required to demonstrate that the product meets the requirements of the R&TTE directive The end-product manufacturer is fully responsible for the compliance of the end-product. The modules test reports can partly be used to demonstrate the compliance but typically all the radiated tests must be re-tested with the end product. All the conducted RF tests can be inherited from the modules test reports because the conducted RF characteristics are not dependent on the installation of the module. Standard Description Tested with the module Test required for the end product Modules test results can be inherited to the end product test report EN 300 328 RF emissions Module fully tested Radiated test cases Yes (partly) EN 301 489-1 EN 301 489-17 EMC immunity and emissions Only EM field immunity tested All the test cases relevant for the end product No Evaluation required in case of multiple radios in colocation. No Full evaluation with the end product No EN 62479 Human exposure to EM fields EN 60950 Safety Not tested. The module is compliant without testing because the TX power is less than 20 mW Not tested because there aren't any test cases that would concern the module Table 23: CE standards summary for WT32i Silicon Labs Page 57 of 63 Note: Because all the radiated emissions must be tested with the end product in any case and because the end product manufacturer is fully responsible for the compliance of the end product, any antenna can be selected for WT32i-E, not just the antenna type that Bluegiga has used in the CE approvals. 15.3 FCC Certification of an End Product In FCC there are three different levels of product authorization: * VERIFICATION o Required for digital devices. The end product manufacturer verifies device to FCC rules by performing the required tests and maintains the records in case of questions * DECLARATION OF CONFORMITY o Required for computer peripherals and receivers. The product manufacturer tests the emissions in a FCC recognized lab according to the relevant standards, maintains the records in case of questions and creates DoC which is supplied with the device. FCC logo must be placed on the product. The information about the DoC is shown in the user manual * CERTIFICATION o Required for most of the radio products. The radio has its own FCC ID and gets listed in FCC files https://apps.fcc.gov/oetcf/eas/reports/GenericSearch.cfm. The FCC ID is labeled on the product. When using modular certified module, re-certification with the end product is not needed provided that the conditions shown in the modules grant are fulfilled. The end product manufacturer is still responsible for the DoC or the Verification of the end product as required. The limitations and restrictions related to the modular certification of WT32i are described in the FCC grant of the module. If the conditions mentioned in the grant are met, then only labelling the end product with "Contains: QOQWT32I" is required. If the conditions are not met, then there are three options to remove the restriction for the end product: * Class 2 Permissive Change o Can be done either by Bluegiga or an agent authorized by Bluegiga. o The FCC ID of WT32i remains unchanged and the end product labelling requirements do not change * Change of ID o Can be done by authorization of Bluegiga o The FCC ID of WT32i is changed. o The end product is labelled according to the new FCC ID of the module ("Contains: XXXYYYY") o NOTE: Bluegiga will not deliver modules with custom labelling. * New certification of the end product o Done by the end product manufacturer o Test reports of the module can be used to reduce the amount of testing When using WT32i-E, only the antenna types approved with the module can be used. WT32i-E is certified with a standard 2 dBi dipole. Any other type of antenna will require authorisation either through C2PC, Change of ID or new certification. Silicon Labs Page 58 of 63 15.3.1 Co-location with Other Transmitters Co-location means co-transmission, not physical co-location. The radios are not considered to be in colocation when the physical separation is more than 20 cm or if the transmissions overlap less than 30 seconds. When two or more radios are in co-location human exposure must be evaluated as the sum of TX powers from all the radios transmitting simultaneously. The FCC grant of WT32i does not allow co-location so it will require authorization through C2PC, Change of ID or a new certification. 15.4 IC Certification of an End Product IC certification is much like FCC. In IC there are two types of product authorizations: * Verification * Certification When using a modular certified WT32i all that is needed, provided that WT32i is the only radio in the design, is labelling the end product with "Contains IC: 5123ABGTWT32I". The responsibility for the radio certification remains with Bluegiga but the end product manufacturer is still responsible for the verification of the remaining parts of the product. Two main differences that are good to be aware of are: * If the TX power is less than 20 mW human exposure evaluation is not required * The test reports are valid for 1 year from the certification 15.5 MIC Japan Certification of an End Product WT32i has MIC Japan type certification and it can be used directly in the end product without need for recertification of the end product. Currently there aren't any labelling requirements for an end product using a certified module but it is recommended to place some indication to the product that it contains certified radio module. 16 WT32i Certifications 16.1 Bluetooth WT32i is qualified as a Bluetooth 3.0 Controller Subsystem with QDID 49552. By combining with a prequalified Host Subsystem WT32i will make a complete Bluetooth end product without any further testing. Listing an end product will require purchasing a declaration ID from Bluetooth SIG. Declaration ID is required only for certain combination of QDID's and it is only needed to pay once. After receiving the declaration ID, multiple products can be listed with the same combination of QDID's under the same declaration ID. If one of the QDID's under the Declaration ID is changed, then new declaration ID will be required. 16.2 CE WT32i is in conformity with the essential requirements and other relevant requirements of the R&TTE Directive (1999/5/EC). The product is conformity with the following standards and/or normative documents. * EMC (immunity only) EN 301 489-17 V2.1.1 * Radiated emissions EN 300 328 V1.8.1 Silicon Labs Page 59 of 63 * Safety EN60950-1:2006+A11:2009+A1:2010+A12:2011 16.3 FCC WT32i complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. Any changes or modifications not expressly approved by Bluegiga Technologies could void the user's authority to operate the equipment. FCC RF Radiation Exposure Statement: This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. End users must follow the specific operating instructions for satisfying RF exposure compliance. This transmitter meets both portable and mobile limits as demonstrated in the RF Exposure Analysis. This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter except in accordance with FCC multi-transmitter product procedures. OEM Responsibilities to comply with FCC Regulations The WT32i module has been certified for integration into products only by OEM integrators under the following condition: * The transmitter module must not be co-located or operating in conjunction with any other antenna or transmitter except in accordance with FCC multi-transmitter product procedures. As long as the two conditions above are met, further transmitter testing will not be required. However, the OEM integrator is still responsible for testing their end-product for any additional compliance requirements required with this module installed (for example, digital device emissions, PC peripheral requirements, etc.). IMPORTANT NOTE: In the event that these conditions can not be met (for certain configurations or colocation with another transmitter), then the FCC and Industry Canada authorizations are no longer considered valid and the FCC ID and IC Certification Number can not be used on the final product. In these circumstances, the OEM integrator will be responsible for re-evaluating the end product (including the transmitter) and obtaining a separate FCC and Industry Canada authorization. If detachable antennas are used: This radio transmitter has been approved by FCC to operate with a 2.7 dBi dipole antenna. Any antenna of the same type and with equal or less gain can be used with WT32i-E without retesting. Antennas of a different type or higher gain will require authorization from FCC. End Product Labeling The WT32i module is labeled with its own FCC ID. If the FCC ID is not visible when the module is installed inside another device, then the outside of the device into which the module is installed must also display a label referring to the enclosed module. In that case, the final end product must be labeled in a visible area with the following: Silicon Labs Page 60 of 63 "Contains Transmitter Module FCC ID: QOQWT32I" or "Contains FCC ID: QOQWT32I" The OEM integrator has to be aware not to provide information to the end user regarding how to install or remove this RF module or change RF related parameters in the user manual of the end product 16.4 IC IC Statements: WT32i complies with Industry Canada licence-exempt RSS standard(s). Operation is subject to the following two conditions: (1) this device may not cause interference, and (2) this device must accept any interference, including interference that may cause undesired operation of the device. Under Industry Canada regulations, this radio transmitter may only operate using an antenna of a type and maximum (or lesser) gain approved for the transmitter by Industry Canada. To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (e.i.r.p.) is not more than that necessary for successful communication. End Product Labeling The WT32i module is labeled with its own IC Certification Number. If the IC Certification Number is not visible when the module is installed inside another device, then the outside of the device into which the module is installed must also display a label referring to the enclosed module. In that case, the final end product must be labeled in a visible area with the following: "Contains Transmitter Module IC: 5123A-BGTWT32I" or "Contains IC: 5123A-BGTWT32I" The OEM integrator has to be aware not to provide information to the end user regarding how to install or remove this RF module or change RF related parameters in the user manual of the end product If detachable antennas are used: This radio transmitter (identify the device by certification number, or model number ifCategory II) has been approved by Industry Canada to operate 2.7 dBi dipole antenna. Antenna types other than this, having a gain greater than 2.7 dBi, are strictly prohibited for use with this device. 16.4.1 IC Declaration d'IC : Ce dispositif est conforme aux normes RSS exemptes de licence d'Industrie Canada. Son fonctionnement est assujetti aux deux conditions suivantes : (1) ce dispositif ne doit pas provoquer de perturbation et (2) ce Silicon Labs Page 61 of 63 dispositif doit accepter toute perturbation, y compris les perturbations qui peuvent entrainer un fonctionnement non desire du dispositif. Selon les reglementations d'Industrie Canada, cet emetteur radio ne doit fonctionner qu'avec une antenne d'une typologie specifique et d'un gain maximum (ou inferieur) approuve pour l'emetteur par Industrie Canada. Pour reduire les eventuelles perturbations radioelectriques nuisibles a d'autres utilisateurs, le type d'antenne et son gain doivent etre choisis de maniere a ce que la puissance isotrope rayonnee equivalente (P.I.R.E.) n'excede pas les valeurs necessaires pour obtenir une communication convenable. Etiquetage du produit final Le module WT32I est etiquete avec sa propre identification FCC et son propre numero de certification IC. Si l'identification FCC et le numero de certification IC ne sont pas visibles lorsque le module est installe a l'interieur d'un autre dispositif, la partie externe du dispositif dans lequel le module est installe devra egalement presenter une etiquette faisant reference au module inclus. Dans ce cas, le produit final devra etre etiquete sur une zone visible avec les informations suivantes : Contient module emetteur IC : 5123A-BGTWT32I ou Contient IC : 5123A-BGTWT32I Dans le guide d'utilisation du produit final, l'integrateur OEM doit s'abstenir de fournir des informations a l'utilisateur final portant sur les procedures a suivre pour installer ou retirer ce module RF ou pour changer les parametres RF. 16.5 MIC Japan WT32i is has MIC Japan type approval with certification number 209-J00089. WT32i is certified as a module and it can be integrated into an end product without a need for additional MIC radio certification of the end product. 16.6 KCC (South-Korea) WT32i has modular certification in South-Korea with certification ID MSIP-CRM-BGT-WT32i 16.7 Qualified Antenna Types for WT32i-E This device has been designed to operate with a 2.7 dBi dipole antenna. Any antenna of the same type and the same or less gain can be used without additional application to FCC. Silicon Labs Page 62 of 63 Simplicity Studio One-click access to MCU and wireless tools, documentation, software, source code libraries & more. Available for Windows, Mac and Linux! IoT Portfolio www.silabs.com/IoT SW/HW Quality Support and Community www.silabs.com/simplicity www.silabs.com/quality community.silabs.com Disclaimer Silicon Labs intends to provide customers with the latest, accurate, and in-depth documentation of all peripherals and modules available for system and software implementers using or intending to use the Silicon Labs products. Characterization data, available modules and peripherals, memory sizes and memory addresses refer to each specific device, and "Typical" parameters provided can and do vary in different applications. Application examples described herein are for illustrative purposes only. Silicon Labs reserves the right to make changes without further notice to the product information, specifications, and descriptions herein, and does not give warranties as to the accuracy or completeness of the included information. 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