MC13783VK5

Freescale Semiconductor Data Sheet: Technical Data Document Number: MC13783 Rev. 3.5, 7/2009 MC13783 Package Information Plastic Package 10 × 10 mm package MC13783 Power Management and Audio Circuit 1 Introduction The MC13783 is a highly integrated power management and audio component dedicated to handset and portable applications covering GSM, GPRS, EDGE, and UMTS standards. The MC13783 implements high-performance audio functions suited to high-end applications such as smartphones and UMTS handsets. Ordering Information Device Device Marking or Operating Temperature Range Package MC13783 –30 to +85°C MAPBGA-247 Contents 1 2 3 4 5 6 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Signal Descriptions . . . . . . . . . . . . . . . . . . . . 6 Electrical Characteristics . . . . . . . . . . . . . . 16 Functional Description . . . . . . . . . . . . . . . . 17 Package Information . . . . . . . . . . . . . . . . . . 47 Product Documentation . . . . . . . . . . . . . . . . 48 The MC13783 provides the following key benefits: • Full power management and audio functionality in one module optimizes system size. • High level of integration reduces the power management and audio system bill of materials. • Versatile solution offers large possibilities of flexibility through simple programming (64 registers of 24-bit data). • Implemented DVS saves significant battery resources in every mode (compatibility with a large number of processors). • Dual channel voice ADC improves intelligibility. Freescale reserves the right to change the detail specifications as may be required to permit improvements in the design of its products. © Freescale Semiconductor, Inc., 2005–2009. All rights reserved. Introduction The detailed block diagram of the MC13783 in Figure 1 shows the wide functionality of the MC13783, including the following features: • Battery charger interface for wall charging and USB charging • 10 bit ADC for battery monitoring and other readout functions • Buck switchers for direct supply of the processor cores • Boost switcher for backlight and USB on the go supply • Regulators with internal and external pass devices • Transmit amplifiers for two handset microphones and a headset microphone • Receive amplifiers for earpiece, loudspeaker, headset and line out • 13 bit Voice CODEC with dual ADC channel and both narrow and wide band sampling • 13 bit Stereo recording from an analog input source such as FM radio • 16 bit Stereo DAC supporting multiple sample rates • Dual SSI audio bus with network mode for connection to multiple devices • Power control logic with processor interface and event detection • Real time clock and crystal oscillator circuitry • Dual SPI control bus with arbitration mechanism • Multiple backlight drivers and LED control including funlight support • USB FS/LS transceiver with OTG and CEA-936-A Carkit support • Touchscreen interface The main functions of the MC13783 are described in the following sections. A detailed block diagram is shown in Figure 1, on page 3. MC13783 Technical Data, Rev. 3.5 2 Freescale Semiconductor GNDSUB1 GNDSUB2 GNDSUB3 GNDSUB4 GNDSUB5 GNDSUB6 GNDSUB7 GNDSUB8 REFD REFC REFB REFA GNDATLAS VATLAS Tri-Color LED Drive Backlight LED Drive REFATLAS GNDLEDTC LOBATB LEDR3 LEDG3 LEDB3 LEDR2 LEDG2 LEDB2 GNDLEDBL LEDR1 LEDG1 LEDB1 LEDKP LEDAD1 LEDAD2 LEDMD1 LEDMD2 LEDMD3 LEDMD4 GNDCHRG CHRGLED CHRGSE1B CHRGMOD0 CHRGMOD1 CHRGRAW Charger Interface and Control: 4 bit DAC, Clamp, Protection, Trickle Generation Battery Interface & Protection BATTDETB CHRGCTRL BPFET CHRGISNSP CHRGISNSN BP BATTFET BATT BATTISNS Introduction PWR Gate Drive & Chg Pump Audio References VATLAS Gen From Li Cell Voltage / Current Sensing & Translation ADREF ADOUT GNDADC ADIN5 ADIN6 ADIN7 ADIN8 ADIN9 ADIN10 ADIN11 Thermal Warning Detection To Interrupt Section A/D Result A/D Control 10 Bit MUX Trigger Handling A/D Touch BUCK 1A 500 mA O/P Drive SW1AIN SW1AOUT GNDSW1A SW1AFB BUCK 1B 500 mA O/P Drive SW1BIN SW1BOUT GNDSW1B SW1BFB BUCK 2A 500 mA O/P Drive BUCK2B 500 mA O/P Drive BOOST 350 mA O/P Drive LOBAT BP + Ref SPI Arbitra tion SPI A/D Control TSX1 TSX2 TSY1 TSY2 ADTRIG PRIVCC A/D Result To Interrupt Section LDO Monitoring and EOL Detection LDOs Screen Interface Shift Register PRICS PRICLK Primary PRIMOSI Interface Primary SPI Config Reg SPI Combinational Logic SECCS SECCLK SECMOSI SECMISO GNDSPI MC2B 4 Shift Register Registers PRIMISO SECVCC Result Registers To Core Logic SPI Secondary SPI Interface Rbias Rbias MC1LB Rbias Shift Register Microphone Bias MC1LIN Input Selector Amc1l MC1RIN Registers Detect PGA A to D PGA MC13783 Amc1r MC2IN Input Selector Amc2 TXIN DVS CONTROL Shift Register PGA D to A Asp SPM VIOLO Pass FET VIOHI Pass FET VINIOHI VIOHI VDIG Pass FET VINDIG VDIG VRFDIG Pass FET VINRFDIG VRFDIG VRFREF VRFCP VRFBG Pass FETs VINRFREF VRFREF VRFCP VRFBG Pass FETs VINSIM VSIM VESIM VINIOLO VIOLO VINVIB VVIB VVIB Pass FET VGEN Pass FET VINGEN VGEN VCAM Pass FET VINCAM VCAM 5 Voice Codec CDCOUT VINLSP GNDREG1 VRF1 GNDREG2 VRF1DRV VRF1 VRF2 VRF2DRV VRF2 LSPP PGAm Selector Alsp LSPM GNDLSP Stereo D to A LSPL HSR Mixer & Mono Adder & Selector Detect Ahsr HSDET HSPGF Phantom Ground HSPGS Arxin VMMC2 VMMC2DRV VMMC2 SIMEN ESIMEN VIBEN REGEN GPO1 Trim-In-Package Control Logic Detect HSLDET VMMC1DRV VMMC1 4 SPI HSL VMMC1 Regulator External Enable Control PGAst Ahsl To Trimmed Circuits External LDO GPO's Router RXOUTR RXINR RXINL PLLLPF GNDPLL BP VBKUP1 VBKUP2 CSOUT PCUT PLL 32x PLL FS1 Switchers RX1 - Ref SPARE2 GNDUSBA GNDUSBD USBEN UMOD1 UMOD0 UID USBVCC UDATVP ON1B ON2B ON3B CLK32K CLK32KMCU RESETB PWRRDY USEROFF WDI RESETBMCU PRIINT SECINT STANDBYSEC STANDBYPRI VBUS 5V Pass FET VUSB 3.3V Pass FET USB/RS-232 Bus GNDCTRL To Interrupt Section + USB On-The-Go SPARE4 VBUS 32 kHz Buffer VINBUS Enables & Control VUSB Interrupt Inputs Core Control Logic, Timers, & Interrupts ICTEST ICSCAN PUMS1 PUMS2 PUMS3 CLKSEL XTAL2 XTAL1 GNDRTC GNDAUD4 GNDAUD5 GNDAUD3 GNDAUD2 Li Cell Charger USB Car Kit Detect SPI Result Registers 32 kHz Crystal Osc CLIB To Charger + TX2 CLIA - URCVD URXVP URXVM UDP UDM RX2 Ref RTC USE0VM UTXENB 32 kHz Internal Osc Audio Bus Interface LICELL To/From Audio Monitor Timer GPO3 GPO4 MEMHLDDRV Memory Hold LCELL Switch BCL1 GPO2 PWRFAIL Power Fail Detect To USB CEA936 Arx RXOUTL GNDAUD1 VINAUDIO VAUDIO Pass FET VSIM VESIM From USB CEA936 SPP FS2 SW2ABSPB SW3IN SW3OUT SW3FB GNDSW3 Atxin TXOUT TX1 SW2BIN SW2BOUT GNDSW2B SW2BFB VAUDIO A to D PGA SW1ABSPB SW2AIN SW2AOUT GNDSW2A SW2AFB DVSSW1A DVSSW1B DVSSW2A DVSSW2B Secondary MC1RB BCL2 PWGT1EN PWGT1DRV PWGT2EN PWGT2DRV Figure 1. MC13783 Detailed Block Diagram MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 3 Introduction 1.1 Audio The audio section is composed of microphone amplifiers and speaker amplifiers, a voice CODEC, and a stereo DAC. Three microphone amplifiers are available for amplification of two handset microphones and of the headset microphone. The feedback networks are fully integrated for a current input arrangement. A line input buffer amplifier is provided for connecting external sources. All microphones have their own stabilized supply with an integrated microphone sensitivity setting. The microphone supplies can be disabled. The headset microphone supply has a fully integrated microphone detection. Several speaker amplifiers are provided. A bridged earpiece amplifier is available to drive an earpiece. Also, a battery supplied bridged amplifier with thermal protection is included to drive a low ohmic speaker for speakerphone and alert functionality. The performance of this amplifier allows it to be used as well for earpiece drive to support applications with a single transducer combining earpiece, speakerphone and alert functionality, thus avoiding the use of multiple transducers. A left audio out is provided which in combination with a discrete power amplifier and the integrated speaker amplifier allows for a stereo speaker application. Two, single-ended amplifiers are included for the stereo headset drive including headset detection. The stereo headset return path is connected to a phantom ground which avoids the use of large DC decoupling capacitors. The additional stereo receive signal outputs can be used for connection to external accessories like a car kit. Via a stereo line in, external sources such as an FM radio or standalone midi ringer can be applied to the receive path. A voice CODEC with a dual path ADC is implemented following GSM audio requirements. Both narrow band and wide band voice is supported. The dual path ADC allows for conversion of two microphone signal sources at the same time for noise cancellation or stereo applications as well as for stereo recording from sources like FM radio. A 16-bit stereo DAC is available which supports multi-clock modes. An on-board PLL ensures proper clock generation. The voice CODEC and the stereo DAC can be operated at the same time via two interchangeable buses supporting master and slave mode, network mode, as well as the different protocols like I2S. Volume control is included in both transmit and receive paths. The latter also includes a balance control for stereo. The mono adder in the receive path allows for listening to a stereo source on a mono transducer. The receive paths for stereo and mono are separated to allow the two sources to be played back simultaneously on different outputs. The different sources can be analog mixed and two sources on the SSI configured in network mode can be mixed as well. 1.2 Switchers and Regulators The MC13783 provides most of the telephone reference and supply voltages. Four down converters and an up converter are included. The down, or buck, converters provide the supply to the processors and to other low voltage circuits such as IO and memory. The four down converters can be combined into two higher power converters. Dynamic voltage scaling is provided on each of the down converters. This allows under close processor control to adapt the output voltage of the converters to minimize processor current drain. The up, or boost, converter supplies the white backlight LEDs and the MC13783 Technical Data, Rev. 3.5 4 Freescale Semiconductor Introduction regulators for the USB transceiver. The boost converter output has a backlight headroom tracking option to reduce overall power consumption. The regulators are directly supplied from the battery or from the switchers and include supplies for IO and peripherals, audio, camera, multi media cards, SIM cards, memory and the transceivers. Enables for external discrete regulators are included as well as a vibrator motor regulator. A dedicated preamplifier audio output is available for multifunction vibrating transducers. Drivers for power gating with external NMOS transistors are provided including a fully integrated charge pump. This will allow to power down parts of the processor to reduce leakage current. 1.3 Battery Management The MC13783 supports different charging and supply schemes including single path and serial path charging. In single path charging, the phone is always supplied from the battery and therefore always has to be present and valid. In a serial path charging scheme, the phone can operate directly from the charger while the battery is removed or deeply discharged. The charger interface provides linear operation via an integrated DAC and unregulated operation like used for pulsed charging. It incorporates a standalone trickle charge mode in case of a dead battery with LED indicator driver. Over voltage, short circuit and under voltage detectors are included as well as charger detection and removal. The charger includes the necessary circuitry to allow for USB charging and for reverse supply to an external accessory. The battery management is completed by a battery presence detector and an A to D converter that serves for measuring the charge current, battery and other supply voltages as well as for measuring the battery thermistor and die temperature. 1.4 Logic The MC13783 is fully programmable via SPI bus. Additional communication is provided by direct logic interfacing. Default startup of the device is selectable by hard-wiring the power up mode select pins. Both the call processor and the applications processor have full access to the MC13783 resources via two independent SPI busses. The primary SPI bus is able to allow the secondary SPI bus to control all or some of the registers. On top of this an arbitration mechanism is built in for the audio, the power and ADC functions. This together will avoid programming conflicts in case of a dual processor type of application. The power cycling of the phone is driven by the MC13783. It has the interfaces for the power buttons and dedicated signaling interfacing with the processor. It also ensures the supply of the memory and other circuits from the coin cell in case of brief power failures. A charger for the coin cell is included as well. Several pre-selectable power modes are provided such as SDRAM self refresh mode and user off mode. The MC13783 provides the timekeeping based on an integrated low power oscillator running with a standard watch crystal. This oscillator is used for internal clocking, the control logic, and as a reference for the switcher PLL. The timekeeping includes time of day, calendar and alarm. The clock is put out to the processors for reference and deep sleep mode clocking. MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 5 Signal Descriptions 1.5 Miscellaneous Functions The drivers and comparators for a USB On-the-Go and a CEA-936-A compatible USB carkit including audio routing, as well as RS232 interfaces are provided. Special precautions are taken to allow for specific booting and accessory detection modes. Current sources are provided to drive tricolored funlights and signaling LEDs. The funlights have preprogrammed lighting patterns. The wide programmability of the tricolored LED drivers allows for applications such as audio modulation. Three backlight drivers with auto dimming are included as well for keypad and dual display backlighting. A dedicated interface in combination with the A to D converter allow for precise resistive touchscreen reading. Pen touch wake up is included. 2 Signal Descriptions The below pinout description gives the pin name per functional block with its row-column coordinates, its maximum voltage rating, and a functional description. Table 1. Pinout Listing Pin Location Rating* Function CHRGRAW A18 A19 B19 EHV 1. Charger input 2. Output to battery supplied accessories CHRGCTRL C18 EHV Driver output for charger path FETs M1 and M2 BPFET B15 EHV 1. Driver output for dual path regulated BP FET M4 2. Driver output for separate USB charger path FETs M5 and M6 CHRGISNSP B17 MV Charge current sensing point 1 CHRGISNSN C14 MV Charge current sensing point 2 BP B13 MV 1. Application supply point 2. Input supply to the MC13783 core circuitry 3. Application supply voltage sense BATTFET A12 MV Driver output for battery path FET M3 BATTISNS A14 MV Battery current sensing point 1 BATT D15 MV 1. Battery positive terminal 2. Battery current sensing point 2 3. Battery supply voltage sense CHRGMOD0 D17 LV Selection of the mode of charging CHRGMOD1 A16 LV Selection of the mode of charging Charger * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 6 Freescale Semiconductor Signal Descriptions Table 1. Pinout Listing (continued) Pin Location Rating* Function CHRGSE1B F15 LV CHRGLED D13 EHV GNDCHRG J11 — LEDMD1 B8 EMV Main display backlight LED driver output 1 LEDMD2 F9 EMV Main display backlight LED driver output 2 LEDMD3 E9 EMV Main display backlight LED driver output 3 LEDMD4 C9 EMV Main display backlight LED driver output 4 LEDAD1 C8 EMV Auxiliary display backlight LED driver output 1 LEDAD2 E8 EMV Auxiliary display backlight LED driver output 2 LEDKP C7 EMV Keypad lighting LED driver output LEDR1 B10 EMV Tricolor red LED driver output 1 LEDG1 E11 EMV Tricolor green LED driver output 1 LEDB1 F11 EMV Tricolor blue LED driver output 1 LEDR2 E10 EMV Tricolor red LED driver output 2 LEDG2 F10 EMV Tricolor green LED driver output 2 LEDB2 G10 EMV Tricolor blue LED driver output 2 LEDR3 F8 EMV Tricolor red LED driver output 3 LEDG3 C10 EMV Tricolor green LED driver output 3 LEDB3 B9 EMV Tricolor blue LED driver output 3 GNDLEDBL H10 — Ground for backlight LED drivers GNDLEDTC J10 — Ground for tricolor LED drivers VATLAS C12 LV Regulated supply output for the MC13783 core circuitry REFATLAS B11 LV Main bandgap reference GNDATLAS H11 — Ground for the MC13783 core circuitry SW1AIN K18 MV Switcher 1A input SW1AOUT K17 MV Switcher 1A output SW1AFB L18 LV Switcher 1A feedback Charger forced SE1 detection input Trickle LED driver output Ground for charger interface LED Drivers MC13783 Core Switchers * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 7 Signal Descriptions Table 1. Pinout Listing (continued) Pin Location Rating* Function DVSSW1A J15 LV Dynamic voltage scaling logic input for switcher 1A GNDSW1A L17 — Ground for switcher 1A SW1BIN N18 MV Switcher 1B input SW1BOUT N17 MV Switcher 1B output SW1BFB M18 LV Switcher 1B feedback DVSSW1B K15 LV Dynamic voltage scaling logic input for switcher 1B GNDSW1B M17 — Ground for switcher 1B SW2AIN P18 MV Switcher 2A input SW1ABSPB P11 LV SW1 mode configuration SW2AOUT R18 MV Switcher 2A output SW2AFB P15 LV Switcher 2A feedback DVSSW2A H15 LV Dynamic voltage scaling logic input for switcher 2A GNDSW2A P17 — Ground for switcher 2A SW2BIN U18 MV Switcher 2B input SW2BOUT T18 MV Switcher 2B output SW2BFB R17 LV Switcher 2B feedback DVSSW2B J14 LV Dynamic voltage scaling logic input for switcher 2B GNDSW2B T17 — Ground for switcher 2B SW2ABSPB R12 LV SW2 mode configuration SW3IN J17 HV Switcher 3 input SW3OUT H18 HV Switcher 3 output SW3FB H17 HV Switcher 3 feedback GNDSW3 J18 — Ground for switcher 3 PWGT1EN L14 LV Power gate driver 1 enable PWGT1DRV M15 EMV Power gate driver 1 output PWGT2EN L15 LV Power gate driver 2 enable PWGT2DRV K14 EMV Power gate driver 2 output U12 MV Power Gating Regulators VINAUDIO Input regulator audio * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 8 Freescale Semiconductor Signal Descriptions Table 1. Pinout Listing (continued) Pin Location Rating* Function VAUDIO U10 LV Output regulator audio VINIOLO U13 MV Input regulator low voltage IO VIOLO V13 LV Output regulator low voltage IO VINIOHI B7 MV Input regulator high voltage IO VIOHI B6 LV Output regulator high voltage IO VINDIG R11 MV Input regulator general digital VDIG U11 LV Output regulator general digital VINRFDIG K5 MV Input regulator transceiver digital VRFDIG K2 LV Output regulator transceiver digital VINRFREF K7 MV Input regulator transceiver reference VRFREF G3 LV Output regulator transceiver reference VRFCP G2 LV Output regulator transceiver charge pump VRFBG C11 LV Bandgap reference output for transceiver VINSIM F2 MV Input regulator SIM card and eSIM card VSIM E3 LV Output regulator SIM card VESIM F3 LV Output regulator eSIM card VINVIB G5 MV Input regulator vibrator motor VVIB E2 LV Output regulator vibrator motor VINGEN G17 MV Input regulator graphics accelerator VGEN G18 LV Output regulator graphics accelerator VINCAM V12 MV Input regulator camera VCAM V11 LV Output regulator camera VRF2DRV J6 MV Drive output regulator transceiver VRF2 J5 LV Output regulator transceiver VRF1DRV K8 MV Drive output regulator transceiver VRF1 J3 LV Output regulator transceiver VMMC1DRV L7 MV Drive output regulator MMC1 module VMMC1 K6 LV Output regulator MMC1 module VMMC2DRV J2 MV Drive output regulator MMC2 module VMMC2 K3 LV Output regulator MMC2 module * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 9 Signal Descriptions Table 1. Pinout Listing (continued) Pin Location Rating* Function SIMEN D19 LV VSIM enable input ESIMEN F16 LV VESIM enable input VIBEN E19 LV VVIB enable input REGEN E18 LV Regulator enable input GPO1 G8 LV General purpose output 1 to be used for enabling a discrete regulator GPO2 F6 LV General purpose output 2 to be used for enabling a discrete regulator GPO3 E5 LV General purpose output 3 to be used for enabling a discrete regulator GPO4 G9 LV General purpose output 4 to be used for enabling a discrete regulator GNDREG1 N12 — Ground for regulators 1 GNDREG2 K10 — Ground for regulators 2 UDP C2 EMV 1. USB transceiver cable interface, D+ 2. RS232 transceiver cable interface, transmit output or receive input signal UDM D2 EMV 1. USB transceiver cable interface, D2. RS232 transceiver cable interface, receive input or transmit output signal UID F7 EMV USB on the go transceiver cable ID resistor connection UDATVP C5 LV 1. USB processor interface transmit data input (logic level version of D+/D-) or transmit positive data input (logic level version of D+) 2. Optional USB processor interface receive data output (logic level version of D+/D-) 3. RS232 processor interface USE0VM C6 LV 1. USB processor interface transmit single ended zero signal input or transmit minus data input (logic level version of D-) 2. Optional USB processor interface received single ended zero output 3. Optional RS232 processor interface UTXENB C4 LV 1. USB processor interface transmit enable bar URCVD B5 LV Optional USB receiver processor interface differential data output (logic level version of D+/D-) URXVP B3 LV Optional USB receiver processor interface data output (logic level version of D+) URXVM B2 LV 1. Optional USB receiver processor interface data output (logic level version of D-) 2. Optional RS232 processor interface UMOD0 H7 LV USB transceiver operation mode selection at power up 0 UMOD1 G6 LV USB transceiver operation mode selection at power up 1 USBEN C3 LV Bootmode enable for USB/RS232 interface VINBUS B4 EMV USB/RS232 Input for VBUS and VUSB regulators for USB on the go mode * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 10 Freescale Semiconductor Signal Descriptions Table 1. Pinout Listing (continued) Pin VBUS Location Rating* D3 EHV EMV Function When in common input configuration, shorted to CHRGRAW 1. USB transceiver cable interface VBUS 2. Output VBUS regulator in USB on the go mode When in separate input configuration, not shorted to CHRGRAW 1. USB transceiver cable interface VBUS 2. Output VBUS regulator in USB on the go mode VUSB F5 MV Output VUSB regulator as used by the USB transceiver USBVCC E7 LV Supply for processor interface GNDUSBA A1 A2 B1 — Ground for USB transceiver and USB cable GNDUSBD K9 — Ground for USB processor interface ON1B E16 LV Power on/off button connection 1 ON2B E15 LV Power on/off button connection 2 ON3B G14 LV Power on/off button connection 3 WDI F17 LV Watchdog input RESETB G15 LV Reset output RESETBMCU F18 LV Reset for the processor STANDBYPRI H14 LV Standby input signal from primary processor STANDBYSEC J13 LV Standby input signal from secondary processor LOBATB N14 LV Low battery indicator signal or end of life indicator signal PWRRDY U17 LV Power ready signal after DVS and power gate transition PWRFAIL F13 LV Powerfail indicator output to processor or system USEROFF E14 LV User off signaling from processor MEMHLDDRV G12 LV Memory hold FET drive for power cut support CSOUT G11 LV Chip select output for memory LICELL C16 MV 1. Coincell supply input 2. Coincell charger output VBKUP1 E12 LV Backup output voltage for memory VBKUP2 F12 LV Backup output voltage for processor core GNDCTRL J12 — Ground for control logic Control Logic * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 11 Signal Descriptions Table 1. Pinout Listing (continued) Pin Location Rating* Function Oscillator and Real Time Clock XTAL1 V16 LV 32.768 kHz Oscillator crystal connection 1 XTAL2 V14 LV 32.768 kHz Oscillator crystal connection 2 CLK32K R14 LV 32 kHz Clock output CLK32KMCU E13 LV 32 kHz Clock output to the processor CLKSEL U16 LV Enables the RC clock routing to the outputs GNDRTC V15 — Ground for the RTC block PUMS1 H6 LV Power up mode supply setting 1 PUMS2 J7 LV Power up mode supply setting 2 PUMS3 H5 LV Power up mode supply setting 3 ICTEST F14 LV Test mode selection ICSCAN U14 LV Scan mode selection PRIVCC N2 LV Supply for primary SPI bus and audio bus 1 PRICLK N5 LV Primary SPI clock input PRIMOSI N8 LV Primary SPI write input PRIMISO P7 LV Primary SPI read output PRICS N6 LV Primary SPI select input PRIINT P5 LV Interrupt to processor controlling the primary SPI bus SECVCC N3 LV Supply for secondary SPI bus and audio bus 2 SECCLK P6 LV Secondary SPI clock input SECMOSI R6 LV Secondary SPI write input SECMISO R5 LV Secondary SPI read output SECCS P8 LV Secondary SPI select input SECINT R7 LV Interrupt to processor controlling the secondary SPI bus GNDSPI L9 LV Ground for SPI interface BATTDETB K13 LV Battery thermistor presence detect output ADIN5 M14 LV ADC generic input channel 5, group 1 Power Up Select SPI Interface A to D Converter * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 12 Freescale Semiconductor Signal Descriptions Table 1. Pinout Listing (continued) Pin Location Rating* Function ADIN6 U15 LV ADC generic input channel 6, group 1 ADIN7 R15 LV ADC generic input channel 7, group 1 ADIN8 P14 LV ADC generic input channel 8, group 2 ADIN9 V17 LV ADC generic input channel 9, group 2 ADIN10 V18 LV ADC generic input channel 10, group 2 ADIN11 V19 W18 W19 LV ADC generic input channel 11, group 2 TSX1 P13 LV ADC generic input channel 12 or touchscreen input X1, group 2 TSX2 L13 LV ADC generic input channel 13 or touchscreen input X2, group 2 TSY1 P12 LV ADC generic input channel 14 or touchscreen input Y1, group 2 TSY2 M13 LV ADC generic input channel 15 or touchscreen input Y2, group 2 ADREF R13 LV Reference for ADC and touchscreen interface ADTRIG N15 LV ADC trigger input ADOUT E6 LV ADC trigger output GNDADC L12 — Ground for A to D circuitry BCL1 M7 LV Bit clock for audio bus 1. Input in slave mode, output in master mode FS1 M9 LV Frame synchronization clock for audio bus 1. Input in slave mode, output in master mode RX1 L5 LV Receive data input for audio bus 1 TX1 M6 LV Transmit data output for audio bus 1 BCL2 M8 LV Bit clock for audio bus 2. Input in slave mode, output in master mode FS2 M2 LV Frame synchronization clock for audio bus 2. Input in slave mode, output in master mode RX2 M3 LV Receive data input for audio bus 2 TX2 M5 LV Transmit data output for audio bus 2 CLIA L6 LV Clock input for audio bus 1 or 2 CLIB L3 LV Clock input for audio bus 1 or 2 MC1RB R2 LV Handset primary or right microphone supply output with integrated bias resistor MC1LB P3 LV Handset secondary or left microphone supply output with integrated bias resistor Audio Bus Audio Transmit * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 13 Signal Descriptions Table 1. Pinout Listing (continued) Pin Location Rating* Function MC2B P2 LV Headset microphone supply output with integrated bias resistor and detect MC1RIN V2 LV Handset primary or right microphone amplifier input MC1LIN U2 LV Handset secondary or left microphone amplifier input MC2IN U3 LV Headset microphone amplifier input TXIN U4 LV General purpose line level transmit input TXOUT V3 LV Buffered output of CEA-936-A microphone signal SPP V9 LV Handset earpiece speaker amplifier output positive terminal SPM V10 LV Handset earpiece speaker amplifier output minus terminal VINLSP V6 MV Handset loudspeaker and alert amplifier supply input LSPP V5 MV Handset loudspeaker and alert amplifier positive terminal LSPM V4 MV Handset loudspeaker and alert amplifier minus terminal GNDLSP V1 W1 W2 — Ground for loudspeaker amplifier LSPL U5 LV Low power output for discrete loudspeaker amplifier, associated to left channel audio CDCOUT U6 LV Low power output for discrete amplifier, associated to voice CODEC channel HSL V8 LV Headset left channel amplifier output HSR U9 LV Headset right channel amplifier output HSPGF V7 LV Headset phantom ground power line (force) HSPGS P10 LV Headset phantom ground feedback line (sense) HSDET R10 LV Headset sleeve detection input HSLDET R8 LV Headset left detection input RXOUTR U7 LV Low power receive output for accessories right channel RXOUTL P9 LV Low power receive output for accessories left channel RXINR R9 LV General purpose receive input right channel RXINL U8 LV General purpose receive input left channel REFA R3 LV Reference for audio amplifiers REFB T3 LV Reference for low noise audio bandgap REFC T2 LV Reference for voice CODEC Audio Receive Audio Other * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 14 Freescale Semiconductor Signal Descriptions Table 1. Pinout Listing (continued) Pin Location Rating* Function REFD L2 LV Reference for stereo DAC PLLLPF H2 LV Connection for the stereo DAC PLL low pass filter. GNDPLL H3 — Dedicated ground for the stereo DAC PLL block. GNDAUD1 L10 — Ground for audio circuitry 1 (analog) GNDAUD2 M10 — Ground for audio circuitry 2 (analog) GNDAUD3 M11 — Ground for audio circuitry 3 (analog) GNDAUD4 M12 — Ground for audio circuitry 4 (digital) GNDAUD5 H9 — Ground for audio circuitry 5 (digital) GNDSUB1 N11 — Non critical signal ground and thermal heatsink GNDSUB2 K12 — Non critical signal ground and thermal heatsink GNDSUB3 K11 — Non critical signal ground and thermal heatsink GNDSUB4 H12 — Non critical signal ground and thermal heatsink GNDSUB5 J9 — Non critical signal ground and thermal heatsink GNDSUB6 J8 — Non critical signal ground and thermal heatsink GNDSUB7 L8 — Non critical signal ground and thermal heatsink GNDSUB8 L11 — Non critical signal ground and thermal heatsink SPARE2 H8 TBD Spare ball for future use SPARE4 H13 TBD Spare ball for future use Thermal Grounds Future Use * The maximum voltage rating is given per category of pins: • EHV for Extended High Voltage (20 V) • HV for High Voltage (7.5 V) • EMV for Extended Medium Voltage (5.5 V) • MV for Medium Voltage (4.65 V) • LV for Low Voltage (3.1 V) MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 15 Electrical Characteristics 3 3.1 Electrical Characteristics Absolute Maximum Ratings Table 2 gives the maximum allowed voltages, current and temperature ratings which can be applied to the IC. Exceeding these ratings could damage the circuit. Table 2. Absolute Maximum Ratings Parameter 3.2 Min Typ Max Units Charger Input Voltage -0.3 — +20 V USB Input Voltage if Common to Charger -0.3 — +20 V USB Input Voltage if Separate from Charger -0.3 — +5.50 V Battery Voltage -0.3 — +4.65 V Coincell Voltage -0.3 — +4.65 V Ambient Operating Temperature Range -30 — +85 °C Operating Junction Temperature Range -30 — +125 °C Storage Temperature Range -65 — +150 °C ESD Protection Human Body Model 2.0 — — kV Current Consumption The current consumption of the individual blocks is described in detail throughout this specification. For convenience, below a summary table is included with the main characteristics. Note that the external loads are not taken into account. Table 3. Summary of Current Consumption Mode Typ Max Unit RTC 5 6 µA OFF 30 45 µA Power Cut 35 52 µA User OFF 60 91 µA ON Standby 135 220 µA ON Default 620 1000 µA ON Audio Call 7.3 9.9 mA ON Stereo Playback 9.5 12.1 mA MC13783 Technical Data, Rev. 3.5 16 Freescale Semiconductor Functional Description 4 Functional Description 4.1 Logic The logic portions of the MC13783 includes the following: • Section 4.1.1, “Programmability,” on page 17 includes a description of the dual SPI interface. • Section 4.1.2, “Clock Generation and Real Time Clock,” on page 21 includes a description of the 32.768 kHz real time clock generation. • Section 4.1.3, “Power Control System,” on page 22 describes the power control logic, including interface and operated modes. 4.1.1 4.1.1.1 Programmability SPI Interface The MC13783 IC contains two SPI interface ports which allow parallel access by both the call processor and the applications processor to the MC13783 register set. Via these registers the MC13783 resources can be controlled. The registers also provide status information about how the MC13783 IC is operating as well as information on external signals. The SPI interface is comprised of the signals listed below. Table 4. SPI Interface Pin Description Description SPI Bus PRICLK Primary processor clock input line, data shifting occurs at the rising edge. PRIMOSI Primary processor serial data input line. PRIMISO Primary processor serial data output line. PRICS Primary processor clock enable line, active high. SECCLK Secondary processor clock input line, data shifting occurs at the rising edge. SECMOSI Secondary processor serial data input line. SECMISO Secondary processor serial data output line. SECCS Secondary processor clock enable line, active high. Interrupt PRIINT Primary processor interrupt. SECINT Secondary processor interrupt. Supply PRIVCC Primary processor SPI bus supply. SECVCC Secondary processor SPI bus supply Both SPI ports are configured to utilize 32-bit serial data words, using 1 read/write bit, 6 address bits, 1 null bit, and 24 data bits. The SPI ports’ 64 registers correspond to the 6 address bits. MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 17 Functional Description 4.1.1.2 Register Set The register set is given in Table 5. Table 5. Register Set Register Register Register Register 0 Interrupt Status 0 16 Regen Assignment 32 Regulator Mode 0 48 Charger 1 Interrupt Mask 0 17 Control Spare 33 Regulator Mode 1 49 USB 0 2 Interrupt Sense 0 18 Memory A 34 Power Miscellaneous 50 Charger USB 1 3 Interrupt Status 1 19 Memory B 35 Power Spare 51 LED Control 0 4 Interrupt Mask 1 20 RTC Time 36 Audio Rx 0 52 LED Control 1 5 Interrupt Sense 1 21 RTC Alarm 37 Audio Rx 1 53 LED Control 2 6 Power Up Mode Sense 22 RTC Day 38 Audio Tx 54 LED Control 3 7 Identification 23 RTC Day Alarm 39 SSI Network 55 LED Control 4 8 Semaphore 24 Switchers 0 40 Audio Codec 56 LED Control 5 9 Arbitration Peripheral Audio 25 Switchers 1 41 Audio Stereo DAC 57 Spare 10 Arbitration Switchers 26 Switchers 2 42 Audio Spare 58 Trim 0 11 Arbitration Regulators 0 27 Switchers 3 43 ADC 0 59 Trim 1 12 Arbitration Regulators 1 28 Switchers 4 44 ADC 1 60 Test 0 13 Power Control 0 29 Switchers 5 45 ADC 2 61 Test 1 14 Power Control 1 30 Regulator Setting 0 46 ADC 3 62 Test 2 15 Power Control 2 31 Regulator Setting 1 47 ADC 4 63 Test 3 4.1.1.3 4.1.1.3.1 Interface Requirements SPI Interface Description The operation of both SPI interfaces is equivalent. Therefore, all SPI bus names without prefix PRI or SEC correspond to both the PRISPI and SECSPI interfaces. The control bits are organized into 64 fields. Each of these 64 fields contains 32 bits. A maximum of 24 data bits is used per field. In addition, there is one “dead” bit between the data and address fields. The remaining bits include 6 address bits to address the 64 data fields and one write enable bit to select whether the SPI transaction is a read or a write. For each SPI transfer, first a one is written to the read/write bit if this SPI transfer is to be a write. A zero is written to the read/write bit if this is to be a read command only. If a zero is written, then any data sent after the address bits are ignored and the internal contents of the field addressed do not change when the 32nd CLK is sent. Next the 6-bit address is written, MSB first. Finally, data bits are written, MSB first. Once all the data bits are written then the data is transferred into the actual registers on the falling edge of the 32nd CLK. MC13783 Technical Data, Rev. 3.5 18 Freescale Semiconductor Functional Description The default CS polarity is active high. The CS line must remain active during the entire SPI transfer. In case the CS line goes inactive during a SPI transfer all data is ignored. To start a new SPI transfer, the CS line must go inactive and then go active again. The MISO line will be tri-stated while CS is low. Note that not all bits are truly writable. Refer to the individual subcircuit descriptions to determine the read/write capability of each bit. All unused SPI bits in each register must be written to a zero. SPI readbacks of the address field and unused bits are returned as zero. To read a field of data, the MISO pin will output the data field pointed to by the 6 address bits loaded at the beginning of the SPI sequence. CS CLK MOSI Write_En Address5 Address4 Address3 Address2 Address 1 Address 0 “Dead Bit” MISO Data 23 Data 22 Data 1 Data 0 Data 23 Data 22 Data 1 Data 0 Figure 2. SPI Transfer Protocol Single Read/Write Access CS Preamble MOSI MISO First Address 24 Bits Data 24 Bits Data Preamble Another Address 24 Bits Data 24 Bits Data Figure 3. SPI Transfer Protocol Multiple Read/Write Access 4.1.1.3.2 SPI Requirements The requirements for both SPI interfaces are equivalent. Therefore, all SPI bus names without prefix PRI or SEC correspond to both SPI interfaces. The below diagram and table summarize the SPI electrical and timing requirements. The SPI input and output levels are set independently via the PRIVCC and SECVCC pins by connecting those to the proper supply. MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 19 Functional Description Tclkper CS Tclkhigh Tselsu Tclklow Tsellow Tselhld CLK Twrtsu Twrthld MOSI Trdsu Trden Trddis Trdhld MISO Figure 4. SPI Interface Timing Diagram Table 6. SPI Interface Timing Specifications Parameter Description T min (ns) Tselsu Time CS has to be high before the first rising edge of CLK 20 Tselhld Time CS has to remain high after the last falling edge of CLK 20 Tsellow Time CS has to remain low between two transfers 20 Tclkper Clock period of CLK1 50 Tclkhigh Part of the clock period where CLK has to remain high 20 Tclklow Part of the clock period where CLK has to remain low 20 Twrtsu Time MOSI has to be stable before the next rising edge of CLK 5 Twrthld Time MOSI has to remain stable after the rising edge of CLK 5 Trdsu Time MISO will be stable before the next rising edge of CLK 5 Trdhld Time MISO will remain stable after the falling edge of CLK 5 Trden Time MISO needs to become active after the rising edge of CS 5 Trddis Time MISO needs to become inactive after the falling edge of CS 5 1 Equivalent to a maximum clock frequency of 20 MHz. Table 7. SPI Interface Logic IO Specifications Parameter Condition Min Max Units Input High CS, MOSI, CLK — 0.7*VCC VCC+0.5 V Input Low CS, MOSI, CLK — 0 0.3*VCC V 0 0.2 V VCC-0.2 VCC V Output Low MISO, INT Output sink 100 μA Output High MISO, INT Output source 100 μA Note: VCC refers to PRIVCC and SECVCC respectively. MC13783 Technical Data, Rev. 3.5 20 Freescale Semiconductor Functional Description 4.1.2 4.1.2.1 Clock Generation and Real Time Clock Clock Generation The MC13783 generates a 32.768 kHz clock as well as several 32.768 kHz derivative clocks that are used internally for control. In addition, a 32.768 kHz square wave is output to external pins. 4.1.2.1.1 Clocking Scheme The MC13783 contains an internal RC oscillator powered from VATLAS that delivers a 32 kHz nominal frequency (±20%) at its output when an external 32.768 kHz crystal is not present. The RC oscillator will then be used to run the debounce logic, the PLL for the switchers, the real time clock (RTC) and internal control logic, and can also be output on the CLK32K pin. 4.1.2.2 Real Time Clock This section provides an overview of the Real Time Clock (RTC). 4.1.2.2.1 Time and Day Counters The real time clock runs from the 32 kHz clock. This clock is divided down to a 1 Hz time tick which drives a 17 bit time of day (TOD) counter. The TOD counter counts the seconds during a 24 hour period from 0 to 86,399 and will then roll over to 0. When the roll over occurs, it increments the 15-bit DAY counter. The DAY counter can count up to 32767 days. The 1Hz time tick can be used to generate an 1HZI interrupt. The 1HZI can be masked with corresponding 1HZM mask bit. If the TOD and DAY registers are read at a point in time in which DAY is incremented, then care must be taken that, if DAY is read first, DAY has not changed before reading TOD. In order to guarantee stable TOD and DAY data, all SPI reads and writes to TOD and DAY data should happen immediately after the 1HZI interrupt occurs. Alternatively, TOD or DAY readbacks could be double-read and then compared to verify that they haven't changed. This requirement results from the fact that the 32.768 kHz clock is completely independent of the SPI clock and the two cannot be synchronized. 4.1.2.2.2 Time of Day Alarm A Time Of Day (TOD) alarm function can be used to turn on the phone and alert the processor. If the phone is already on, the processor will be interrupted. The TODA and DAYA registers are used to set the alarm time. When the TOD counter is equal to the value in TODA and the DAY counter is equal to the value in DAYA, the TODAI interrupt will be generated. MC13783 makes it convenient to schedule multiple daily events, where a single list could be used, or to skip any number of days. MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 21 Functional Description 4.1.3 Power Control System The power control system on MC13783 interfaces with the processors via different IO signals and the SPI bus. It also uses on-chip signals and detector outputs. It supports a system with different operating modes as described below. Table 8. MC13783 Operating Modes Mode Description Off Only the MC13783 core circuitry at VATLAS and the RTC module are powered. To exit the Off mode requires a turn on event. Cold Start The switchers and regulators are powered up sequentially to limit the inrush current. At the end of the start-up phase, the RESETB and RESETBMCU will be made high and the circuit transitions to On. On The circuit is fully powered and under SPI control. To stay in this mode, the WDI pin has to be high and remain high. If not, the part will transition to Off mode. Memory Hold All switchers and regulators are powered off except for VBKUP1 and VBKUP2. The RESETB and RESETBMCU are low. The MC13783 enters Cold Start mode when a turn on event occurs. User Off All switchers and regulators are powered off except for VBKUP1 and VBKUP2. RESETB is low and RESETBMCU is kept high. The 32 kHz output signal CLK32KMCU can be maintained in this mode as well. The MC13783 enters Warm Start mode when a turn on event occurs. Warm Start The switchers and regulators are powered up sequentially to limit the inrush current. The reset signals RESETB is kept low and RESETBMCU is kept high and CLK32KMCU can be kept active. At the end of the warm start up phase, the RESETB will be made high and the circuit transitions to On. Power Cuts Defined as a momentary loss of power. This can be caused by battery contact bounce or a user-initiated battery swap. The memory and the processor core are automatically backed up in that case by the coin cell depending on the power cut support mode selected. The maximum duration of a power cut as well as the maximum number of power cuts to be supported are programmable. When exiting the power cut mode due to reapplication of power the system will start up again on the main battery and revert back to the battery supplied modes. Turn On Events If the MC13783 is in Off, User Off or Memory Hold mode, the circuit can be powered on via a turn-on event. The turn-on events are listed below. To indicate to the processor which turn-on event occurred, an interrupt bit is associated with each of the turn-on events. ON1B, ON2B or ON3B pulled low, a power on/off button is connected here. • CHRGRAW pulled high which is equivalent to plugging in a charger. • BP crossing the minimum operating threshold which corresponds to attaching a charged battery to the phone. • VBUS pulled high which is equivalent to plugging in a supplied USB cable. • Time of day alarm which allows powering up a phone at a preset time. The default power up state and sequence of the MC13783 is controlled by the power up mode select pins PUMS1, PUMS2 and PUMS3. In total three different sequences and five different default voltage setting combinations are provided. At power up all regulators and switchers are sequentially enabled at equidistant steps of 2ms to limit the inrush current. MC13783 Technical Data, Rev. 3.5 22 Freescale Semiconductor Functional Description 4.2 4.2.1 Switchers and Regulators Supply Flow The switch mode power supplies and the linear regulators are dimensioned to support a supply flow based upon Figure 5. Charger Protect Accessory and Battery Voltage and Current Control Charge Coincell BP RTC Detect USB Memory Memory Backup USB Transceiver Vusb Vbus Boost Switcher Backlight Drivers Buck 2B DVS RGB LED Drivers Vdig Vgen IO and Digital Buck 2A DVS Buck 1B DVS Modem and Apps Processors Buck 1A DVS Vatlas Vaudio Local Supply Local Audio Enables for Discrete Regs Vvib Vsim Vesim Vmmc1 Vmmc2 Vcam Viohi Violo Vrf1, Vrf2, Vrfref, Vrfdig, Vrfbg, Vrfcp Vibrator Motor (e)SIM Card + interface Peripherals and MMC Camera Peripherals and IO Transceivers Figure 5. Supply Distribution The minimum operating voltage for the supply tree, while maintaining the performance as specified, is 3.0 V. For lower voltages the performance may be degraded. Table 9 summarizes supply output voltages. Table 9. Regulator Output Voltages Supply Output (V) SW1A SW1B SW2A Load (mA) 500 0.900 - 1.675 in 25 mV steps, 1.700 - 2.200 in 100 mV steps SW2B 1A 500 500 1A 500 SW3 5.0 / 5.5 350/300 VAUDIO 2.775 200 VIOHI 2.775 200 MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 23 Functional Description Table 9. Regulator Output Voltages (continued) Supply Output (V) Load (mA) VIOLO 1.2/1.3/1.5/.18 150 (Vout < 1.5V)/200 (Vout ≥ 1.5V) VDIG 1.2/1.3/1.5/.18 150 (Vout < 1.3V)/200 (Vout ≥ 1.3V) VRFDIG 1.2/1.5/1.8/1.875 150 (Vout < 1.8V)/200 (Vout ≥ 1.8V) VGEN 1.1/1.2/1.3/1.5/1.8/2.0/2.4/2.775 150 (Vout < 1.5V)/200 (Vout ≥ 1.5V) VCAM 1.5/1.8/2.5/2.55/2.6/2.75/2.8/3.0 150 VRFBG 1.250 0.1 VRFREF 2.475/2.600/2.700/2.775 50 VRFCP 2.700/2.775 50 VSIM 1.8/2.9 60 VESIM 1.8/2.9 60 VVIB 1.3/1.8/2.0/3.0 200 VUSB 2.775/3.3 50 VBUS 5.0 50 VRF1 1.5/1.875/2.7/2.775 350 VRF2 1.5/1.875/2.7/2.775 350 VMMC1 1.6/1.8/2.0/2.6/2.7/2.8/2.9/3.0 350 VMMC2 1.6/1.8/2.0/2.6/2.7/2.8/2.9/3.0 350 Table 10 lists characteristics that apply to MC13783 regulators. Table 11 on page 25 lists characteristics that apply only to the buck switchers. Table 10. Regulator General Characteristics Parameter Operating Input Voltage Range Vinmin to Vinmax Condition Min — Vnom + 0.3 Output Voltage Vout Vinmin < Vin < Vinmax ILmin < IL < ILmax Load Regulation Typ Max Units 4.65 V Vnom - 3% Vnom Vnom + 3% V 1mA < IL < ILmax For any Vinmin < Vin < Vinmax — — 0.20 mV/mA Active Mode Quiescent Current Vinmin < Vin < Vinmax IL = 0 — 20 30 µA Low Power Mode Quiescent Current Vinmin < Vin < Vinmax IL = 0 — 5 10 µA PSRR IL = 75% of ILmax 20 Hz to 20 kHz Vin = Vnom + 1V 50 60 — dB MC13783 Technical Data, Rev. 3.5 24 Freescale Semiconductor Functional Description Table 10. Regulator General Characteristics (continued) Parameter Condition Min Typ Max Units Minimum Bypass Capacitor Value Used as a condition for all other parameters. -35% 2.2 +35% µF Minimum Bypass Capacitor Value for: VRFREF, VRFCP, VIOHI, VSIM, VESIM Used as a condition for all other parameters. -35% 1 — µF Bypass Capacitor Value for VAUDIO Used as a condition for all other parameters. -35% 1 +35% µF Bypass Capacitor Value for VRFBG Used as a condition for all other parameters. — 100 — nF Bypass Capacitor ESR 10 kHz - 1 MHz 0 — 0.1 Ω Table 11. Buck Switcher Characteristics Parameter Condition Min Typ Max Output Voltage 2.8 V < BP < 4.65 V 0 < IL < 500 mA Output Accuracy PWM Mode, including ripple and load regulation -50 — +50 mV Transient Load Response IL from 5 mA to 400 mA in 1μs IL from 400 mA to 5 mA in 1μs — — +/- 25 mV Effective Quiescent Current Consumption PWM MODE — 50 — µA PFM MODE — 15 — µA External Components Inductor -20% 10 +20% µH — — 0.16 Ω Bypass Capacitor -35% 22 +35% µF Bypass Capacitor ESR 0.005 — 0.1 Ω Inductor Resistance 0.900 V to 1.675 V in 25 m V steps 1.700 V to 2.200 V in 100 V steps Units V The buck switchers support dynamic voltage scaling (DVS). The buck switchers are designed to directly supply the processor cores. To reduce overall power consumption, core voltages of processors may be varied depending on the mode the processor is in. The DVS scheme of the buck switchers allows to transition between the different set points in a controlled and smooth manner. For reduced current drain in low power modes, parts of a processor may be power gated, that is to say, the supply to that part of the processor is disabled. To simplify the supply tree and to reduce the number of external components while maintaining flexibility, power gate switch drivers are included. MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 25 Functional Description 4.3 4.3.1 4.3.1.1 Audio Dual Digital Audio Bus Interface The MC13783 is equipped with two independent digital audio busses. Both busses consist of a bit clock, word clock, receive data and transmit data signal lines. Both busses can be redirected to either the voice CODEC or the stereo DAC and can be operated simultaneously. In addition to the afore mentioned signal lines, two system clock inputs are provided which can be selected to drive the voice CODEC or the stereo DAC. In the latter case, a PLL is used to generate the proper internal frequencies. During simultaneous use of the both busses, two different system clocks can be selected by the voice CODEC and the stereo DAC. 4.3.1.2 Voice CODEC protocol The serial interface protocol for the voice CODEC can be used in master and in slave mode. In both modes, it can operate with a short or a long frame sync and data is transmitted and received in a two's compliment format. CDCFS[1:0]=01 Short Frame Sync Length = Bit CDCFSINV=0 CDCBCLINV=0 CDCFS[1:0]=10 Long Frame Sync Length = 16 Bit FS FSync BCL BitCLK TX TX HIGH Z 15 14 13 12 11 10 9 8 7 6 5 4 3 0 0 0 RX Don't Care 15 14 13 12 11 10 9 8 7 6 5 4 3 0 0 0 HIGH Z Don't Care Figure 6. Voice Codec Timing Diagram Example 1 When the voice CODEC is in slave mode, the FS input must remain synchronous to the CLI frequency. In master mode all clocks are internally generated based on the CLI signal. Additional programmability of the interface for both master and slave mode include bus protocol selection and FS and BCL inversion. There is also the possibility to activate the clocking circuitry independent from the voice CODEC. 4.3.1.3 Stereo DAC protocol The serial interface protocol for the stereo DAC supports the industry standard MSB justified mode and an I2S mode. In industry standard mode, FS will be held high for one 16-bit data word and low for the next 16 bits. I2S mode is similar to industry standard mode except that the serial data is delayed one BCL period. Data is received in a two's compliment format. A network mode is also available where the stereo MC13783 Technical Data, Rev. 3.5 26 Freescale Semiconductor Functional Description DAC will operate in its assigned time slot. A total of maximum 4 time slot pairs are supported depending on the settings of the clock speed. In this case, the sync signal is no longer a word select but a short frame sync. In all modes, the polarity of both FS and BCL is programmable by SPI. There is also the possibility to activate the clocking circuitry independent from the stereo DAC. 4.3.1.4 Audio Port Mixing In network mode, the receive data from two right channel time slots and of two left channel time slots can be added. One left/right time slot pair is considered to represent the main audio flow whereas the other time slot pair represents the secondary flow. The secondary flow can be attenuated with respect to the main flow by 0 dB, 6 dB and 12 dB which should be sufficient to avoid clipping of the composite signal. In addition, the composite signal can be attenuated with 0 dB or 6 dB. 4.3.2 4.3.2.1 Voice CODEC A/D Converters The A/D portion of the voice CODEC consists of two A/D converters which convert two incoming analog audio signals into 13-bit linear PCM words at a rate of 8 kHz or 16 kHz. Following the A/D conversion, the audio signal is digitally band pass filtered. The converted voice is available on the audio bus. If both A/D channels are active, the audio bus is operated in a network mode. Table 12. Telephone CODEC A/D Performance Specifications Parameter Condition Min Typ Units REFC+0.68 V Peak Input (+3 dBm0) single ended CODEC PSRR with respect to BP, 0 to 20 kHz 80 90 — dBP Total Distortion (noise and harmonic) at 1.02 kHz (linear) 0 dBm0 8.0 kHz measurement BW out 60 70 — dBP Idle Channel Noise 0 db PGA gain incl. microphone amp — — -72 dBm0P Inband Spurious 0 dBm0 at 1.02 kHz input, 300 Hz to 3.0 kHz (8 kHz sample rate) — — -48 dB 4.3.2.2 REFC-0.68 Max D/A Converter The D/A portion of the voice CODEC converts 13-bit linear PCM words entering at a rate of 8 kHz and 16 kHz into analog audio signals. Prior to this D/A conversion, the audio signal is digitally band-pass filtered. MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 27 Functional Description Table 13. Telephone CODEC D/A Performance Specifications Parameter Condition Peak Output (+3 dBm0) single ended output Min Typ REFC - 1 Max Units REFC + 1 V CODEC PSRR with respect to B+, 20 Hz to 20 kHz, 80 90 — dB Total Distortion (noise and harmonic) at 1.02 kHz, 0 dBm0, 20 kHz measurement BW out 65 75 — dB Idle Channel Noise at CODEC output, BW out = 20 kHz A weighted — -78 -74 dBm0 Inband Spurious 0 dBm0 at 1.02 kHz to 3.4 kHz input. 300 Hz to 20.0 kHz — — -50 dB 4.3.2.3 Clock Modes In master mode the CLI is divided internally to generate the BCL and FS signals. In slave mode these clocks have to be supplied and in that case there is no imposed relationship between BCL and the other clocks as long as it is high enough to support the number of time slots requested. The supported clock rates are 13.0 MHz, 15.36 MHz, 16.8 MHz, 26.0 MHz and 33.6 MHz. 4.3.3 4.3.3.1 Stereo DAC D/A Converter The stereo DAC is based on a 16-bit linear left and right channel D/A converter with integrated filtering. Table 14. Stereo DAC Main Performance Specifications Parameter Condition Min Typ Max Units -0.5 — +0.5 dB Absolute Gain Input at 0 dBFS, from 20 Hz to 20 kHz L/R Gain Mismatch Input at -3 dBFS, 1.02 kHz — 0.2 0.3 dB Dynamic Range (SNDR at -60 dBFS and 1.02 kHz) + 60 dB, 20 kHz BW out, A weighted 92 96 — dB Output PSRR with respect to battery, input at 0 dBFS, from 20 Hz to 20 kHz A weighted 90 — — dB Spurious input at -3 dBFS, from 20 Hz to 20 kHz, 20 kHz BW out Includes idle tones — — -75 dB MC13783 Technical Data, Rev. 3.5 28 Freescale Semiconductor Functional Description 4.3.3.2 Clock Modes The stereo DAC incorporates a PLL to generate the proper clocks in master and in slave modes. The PLL requires an external C//RC loop filter. In Master Mode, the PLL of the Stereo DAC generates FS and BCL signal based on the reference frequency applied through one of the CLI inputs. The CLI frequencies supported are 3.6864 MHz, 12 MHz, 13 MHz, 15.36 MHz, 16.8 MHz, 26 MHz and 33.6 MHz. The PLL will also generate its own master clock MCL used by the stereo DAC itself. In Slave Mode, FS and BCL are applied to the MC13783 and the MCL is internally generated by the PLL based on either FS or BCL. A special mode is foreseen where the PLL is bypassed and CLI can be used as the MCL signal. In this mode, MCLK must be provided with the exact ratio to FS, depending on the sample rate selected. In the network mode, it’s possible to select up to 8 time slots (4 time slot pairs). CLIA STDCSM=1 & STDCCLK=101 ∅ 1 NR CLIB LPF VCO STDCCLKSEL 1 NF STDCCLK[3:0] MCL BCL1 NS NB STDCSM=0 BCL2 1 NO STDCSM=1 & STDCCLK=101 FS1 1 NFS STDCSM=0 FS2 internal master clock MCLint STDCSSISEL Figure 7. Stereo DAC PLL Block Diagram Table 15. Stereo DAC Sample Rate Selection SPI Bits SR3 SR2 SR1 SR0 FS NFS MCL NB BCL 0 0 0 0 8000 512 4096k 16 256k 0 0 0 1 11025 512 5644.8k 16 352.8k 0 0 1 0 12000 512 6144k 16 384k 0 0 1 1 16000 256 4096k 8 512k 0 1 0 0 22050 256 5644.8k 8 705.6k 0 1 0 1 24000 256 6144k 8 768k 0 1 1 0 32000 128 4096k 4 1024k 0 1 1 1 44100 128 5644.8k 4 1411.2k MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 29 Functional Description Table 15. Stereo DAC Sample Rate Selection SPI Bits (continued) SR3 SR2 SR1 SR0 FS NFS MCL NB BCL 1 0 0 0 48000 128 6144k 4 1536k 1 0 0 1 64000 64 4096k 2 2048k 1 0 1 0 96000 64 6144k 2 3072k 1011 to 1111 are reserved combinations 4.3.4 Audio Input Section 4.3.4.1 Microphone Bias Two microphone bias circuits are provided. One circuit supplies up to two handset microphones via the two outputs MC1RB and MC1LB. The second circuit supplies the headset microphone via MC2B. The microphone bias resistors of 2.2 kOhm are included. The bias circuits can be enabled and disabled. The bias MC2B includes a microphone detect circuit which monitors the current flow through the output both when the bias is disabled or enabled. This will generate an interrupt to the processor. In this way the attach and removal of a headset microphone is detected. Also it allows to include a send/end series switch with the microphone for signaling purposes. When the output of the MC2B gets out of regulation, an interrupt is generated. This allows for connecting a switch in parallel to the microphone. Table 16. MC1RB, MC1LB and MC2B Parametric Specifications Parameter Condition Min Typ Max Units 2.23 2.00 2.38 2.10 2.53 2.20 V Microphone Bias Internal Voltage MC1RB, MC1LB IL = 0 MC2B Output Current Source only 0 — 500 µA PSRR with respect to BP 20 Hz - 10 kHz 90 — — dB Output Noise Includes REFA noise CCITT psophometricly weighted — 1.5 3.0 µVrms 4.3.4.2 Microphone Amplifiers Figure 8 on page 31 shows a block diagram of the microphone amplifier section. A selection can be made between one of the three amplified inputs: the handset microphone connected to MC1RIN, the headset microphone connected to MC2IN, and the line input TXIN. The selected channel can be fed into the receive channel for test purposes. In addition a second amplified input channel can be selected for the second handset microphone connected to MC1LIN. The gain towards to voice CODEC can be programmed in 1 dB steps from –8 dB to +23 dB. In addition to the microphone amplifier paths, there is also the possibility to route the stereo line in signal from RXINR and RXINL to the voice CODEC dual ADC section. This allows for 13-bit, 16 kHz sampled stereo recording of an analog source such as FM radio. MC13783 Technical Data, Rev. 3.5 30 Freescale Semiconductor Functional Description Detect Microphone Bias PGAtxL MC2B Rbias MC1RB Rbias MC1LB MC1LIN Amc1L Input Selector PGAtxL Rbias From RXINL Voice Codec Amc1R Input Selector PGAtxR MC1RIN MC2IN Amc2 PGAtxR Atxin To Rx From RXINR TXIN TXOUT From USB Figure 8. Audio Input Section Diagram Table 17. Amplifiers Amc1L, Amc1R, Amc2, Atxin Performance Specifications Parameter Condition Vin = 100 mVpp Min Typ Max Units 11.8 12 12.2 dB Gain (V to V) at 1.0 kHz Input Impedance (V to V) Amc1L, Amc1R, Amc2 — 8.5 10 11.7 kΩ Atxin — — 40 — kΩ Gain (Atxin) TXIN to Voice Codec — -0.2 0 0.2 dB PSRR with respect to BP 20 Hz – 10 kHz inputs AC grounded — — 90 — dB Input Noise input to REFA — — 1 µVRMS CCITT psophometricly weighted MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 31 Functional Description 4.3.5 Audio Output Section 4.3.5.1 Audio Signal Routing Figure 9 on page 32 shows a block diagram of the audio output section is given indicating the routing possibilities. Selector CDCOUT Codec CDCOUTEN SPP Asp SPM ASPEN Codec From Tx VINLSP Right Voice Codec ASPSEL ALSPSEL CDCBYP Alsp LSPM Codec PGArx DAC LSPP ASPEN ALSPEN ALSPEN GNDLSP PGARXEN PGARX[3:0] LSPL Left LSPLEN Stereo DAC Detect Codec Mixer, Adder, Balance AhsR Right Channel DAC Left Channel DAC RXINR Right Arxin Right PGAst ADDCDCIN ADDSTIN ADDRXIN PGAst AHSSEL Mono Adder Balance Phantom Ground AHSREN MONO[1:0] BALLR BAL[2:0] HSPGF HSPGS Codec AhsL Left Left Detect AHSLEN PGASTEN PGAST[3:0] To Tx HSR HSDET HSL HSLDET Codec PGArxin ArxoutR RXOUTR Right ARXOUTREN ARXOUTSEL RXINL Arxin PGArxin Codec ArxoutL Left ARXINEN ARXIN RXOUTL ARXOUTLEN ARXINEN PGARXIN[3:0] To USB Figure 9. Audio Output Section Diagram Four signal sources can be used in the receive path. The voice CODEC receive signal, the voice CODEC transmit signal (for test purposes), the stereo DAC and an external stereo source like an FM radio. The latter can also be routed to the voice CODEC ADC section for recording purposes. Each of the input source signals is amplified via an independently programmable gain amplifier. The amplified signals are fed into a mixer where the different signals can be mixed. The mixed signal goes through a mono adder and balance circuit which can create a mono signal out of the stereo input signals, and allows for balance control. Via the selector, the composite signal is then directed to one or more of the outputs. These are the regular phone earpiece (Asp), the loudspeaker for hands free or ringing (Alsp), the stereo headset (Ahsr, Ahsl) and the stereo line out. The voice CODEC output signal can also follow an independent route to all of the amplifiers via the additional selector inputs. In addition to the amplifiers, low power outputs are available at LSPL and CDCOUT. MC13783 Technical Data, Rev. 3.5 32 Freescale Semiconductor Functional Description 4.3.5.2 Programmable Gain Amplifiers The gain of the audio in both left and right channels is independently controlled in the programmable gain amplifiers to allow for balance control. The input level from the external stereo source can be pre-amplified by Arxin of 18 dB and the programmable gain amplifier PGArxin to get it at the same level as the other sources before going into the audio input mixer block. The amplifiers are programmable in 3 dB steps from –33 dB to +6 dB. 4.3.5.3 Balance, Mixer, Mono Adder and Selector Block The mixer is a summing amplifier where the different input signals can be summed. The relative level between the input signals is to be controlled via the PGArx, PGAst, and PGArxin amplifiers respectively. The mono adder in the stereo channel can be used in four different modes: stereo (right and left channel independent), stereo opposite (left channel in opposite phase), mono (right and left channel added), mono opposite (as mono but with outputs in opposite phase). The balance control allows for attenuating either the right or the left channel with respect to the other channel. The balance control setting is applied independent of which input channel is selected. The selector opens the audio path to the audio amplifiers and can be seen as an analog switch. 4.3.5.4 Earpiece Speaker Amplifier Asp The Asp amplifier drives the earpiece of the phone in a bridge tied load configuration. The feedback network of the Asp amplifier is fully integrated. Table 18. Amplifier Asp Performance Specifications Parameter Condition Differential Output Swing Gain THD (2nd and 3rd) — — Min Typ Max Units 4.0 — — VPP Single Ended, 1.0 kHz Vin = 100 mVpp 3.8 4.0 4.2 dB 1.0 kHz VOUT = 2 Vp — — 0.1 % 1.0 kHz VOUT = 100 mVp — — 0.1 % 1.0 kHz VOUT = 10 mVp — — 0.1 % PSRR with respect to BP 20 Hz – 20 kHz inputs AC grounded A Weighted — 90 — — dB Input Noise A weighted Including PGA Noise — — — 20 μVRMS — — 16 — Ω Load Impedance — MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 33 Functional Description 4.3.5.5 Loudspeaker Amplifier Alsp The concept of the Alsp amplifier is especially developed to be able to drive one loudspeaker during handset, speakerphone and alert modes. It adopts a fully differential topology in order to be able to reach high PSRR performance while Alsp is powered directly by the telephone battery. The feedback network of the Alsp amplifier is fully integrated. Under worst case conditions the dissipation of Alsp is considerable. To protect the amplifier against overheating, a thermal protection is included which shuts down the amplifier when the maximum allowable junction temperature within Alsp is reached. Table 19. Amplifier Alsp Performance Specifications Parameter Differential Output Swing Condition Min Typ Max Units BP = 3.05 V — 5.0 — — VPP BP = 3.4 V in 8Ω — 5.6 — — VPP — 3.05 — 4.65 V Supply Voltage — Gain 1.0 kHz Vin = 100 mVpp 5.8 6 6.2 dB THD (2nd and 3rd) 1.0 kHz, BP = 3.4 V VOUT = 5 Vpp — 3 5 % 1.0 kHz, BP = 4 V VOUT = 5 Vpp — 1 3 % 1.0 kHz VOUT = 1 Vpp — — 0.1 % 1.0 kHz Vout = 10 mVrms — — 0.1 % PSRR with respect to BP 20 Hz – 20 kHz inputs AC grounded A Weighted — 90 — — dB Input Noise A weighted — — — 20 μVRMS Load Impedance Resistance — 6.4 8 38 Ω 4.3.5.6 Headset Amplifiers Ahsr/Ahsl The Ahsr and Ahsl amplifiers are dedicated for amplification to a stereo headset, the Ahsr for the right channel and Ahsl for the left channel. The feedback networks are fully integrated. The return path of the headset is provided by the phantom ground which is at the same DC voltage as the bias of the headset amplifiers. This avoids the use of large sized capacitors in series with the headset speakers. All outputs withstand shorting to ground or to phantom ground. Table 20. Amplifiers Ahsr and Ahsl Performance Specifications Parameter Condition Singled-Ended Output Swing 32 Ohm load 16 Ohm load Gain 1.0 kHz Vin = 100 mVpp Min Typ Max Units 2 1.6 2.2 1.8 — VPP -0.2 0 0.2 dB MC13783 Technical Data, Rev. 3.5 34 Freescale Semiconductor Functional Description Table 20. Amplifiers Ahsr and Ahsl Performance Specifications (continued) Parameter THD (2nd and 3rd) Condition 1.0 kHz Min Typ Max Units VOUT = 1 VPP — 0.03 0.1 % VOUT = 10 mVRMS — 0.03 0.1 % PSRR with respect to BP 20 Hz - 20 kHz inputs AC grounded A Weighted 90 — — dB Input Noise A weighted — — 20 μVRMS Load Impedance Resistance 12.8 16 38 Ω The MC13783 provides a headset detection scheme based on the sleeve detection, left channel impedance detection and microphone bias detection which is valid for headsets with or without phantom ground connection. It is compatible with mono headsets where the left channel is connected to ground. 4.3.5.7 Line Output Amplifier Arxout The Arxout amplifier combination is a low power stereo amplifier. It can provide the stereo signal to for instance an accessory connector. The same output of the selector block is used for the internal connection to the USB transceiver for CEA-936-A Carkit support. Table 21. Arx Performance Specifications Parameter Condition Typ Max Units -0.2 0 +0.2 dB Gain 1.0 kHz Single Ended Output Swing Includes reverse bias protection purpose — 1.8 2 — Vpp PSRR with respect to BP 20 Hz – 20 kHz inputs AC grounded A Weighted — 90 — — dB THD (2nd and 3rd) gain = 0 dB VOUT = 1 VPP — — 0.1 % VOUT = 100 mVRMS — — 0.1 % VOUT = 10 mVRMS (3) — — 0.1 % — 1 — — kΩ — — 15 20 µVRMS External Load Impedance Output Noise Vin = 100 mVpp Min — gain = 0 dB A weighted 20 Hz - 20 kHz Per output (2) MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 35 Functional Description 4.3.6 4.3.6.1 Audio Control Supply The audio section is supplied from a dedicated regulator VAUDIO, except for the loudspeaker amplifier Alsp which is directly supplied from the battery. A low power standby mode controlled by the standby pins is provided for VAUDIO in which the bias current is reduced. The output drive capability and performance are limited in this mode. The nominal output voltage for VAUDIO is 2.775 V. A 1uF (± 35%) bypass capacitor is needed at the output of the VAUDIO regulator. 4.3.6.2 Bias and Anti-Pop The audio blocks have a bias which can be enabled separately from the rest of the MC13783. When enabled, the audio bias voltages can be ramped fast or slow to make any pop sub audio and therefore not audible. 4.3.6.3 Arbitration Logic The audio functions can be operated by both the primary and secondary SPI. 4.4 4.4.1 Battery Management Battery Interface and Control The battery interface is optimized for single charger input coming from a standard wall charger or from a USB bus. The charger has been designed to support three different configurations where the charger and USB bus share the same input pin (CHRGRAW): these are dual path charging, serial path charging, and single path charging. In addition, provisions have been taken for a separate input configuration where the charger and USB supply are on separate inputs. In all cases except for single path charging, the battery interface allows for so called dead battery operation. An example of serial path charging is shown in Section 4.4.1.1, “Serial Path Configuration Example,” on page 37. This section includes the following subsections: • Section 4.4.1.1, “Serial Path Configuration Example,” on page 37 • Section 4.4.1.2, “Charger Operation,” on page 38 • Section 4.4.1.3, “Coin Cell,” on page 38 The mode of operation for the charger interface is selected via the CHRGMOD1 and CHRGMOD0 pins as given in Table 22. Table 22. Charger Mode Selection CHRGMOD1 CHRGMOD0 Charger Mode Hi Z GND Dual Path Hi Z Hi Z Single Path Hi Z VATLAS Serial Path MC13783 Technical Data, Rev. 3.5 36 Freescale Semiconductor Functional Description Table 22. Charger Mode Selection (continued) 4.4.1.1 CHRGMOD1 CHRGMOD0 Charger Mode VATLAS GND Separate Input Dual Path VATLAS Hi Z Separate Input Single Path VATLAS VATLAS Separate Input Serial Path GND GND Reserved GND Hi Z Reserved GND VATLAS Reserved Serial Path Configuration Example In serial path configuration, the current path used for charging the battery is the same as the supply path from charger to radio B+. Refer to the block diagram example in Figure 10 on page 37. Transistors M1 and M2 control the charge current and provide a voltage clamping function in case of no battery or in case of a dead battery to allow the application to operate. In both cases transistor M3 is non-conducting and the battery is charged with a trickle charge current internal to the MC13783. The transistor M3 is conducting in case the battery has to be connected to the application like for normal operation or for standalone trickle charging. Transistor M2 is non-conducting in case the charger voltage is too high. A current can be supplied from the battery to an accessory by having all transistors M1, M2 and M3 conducting. M1 M2 Charger/USB Input BP or CHRGRAW R1 20 mΩ Hi Z Chrg In Error Amp Charger Detection and OV Block 2 OVCTRL [1:0] + Charge Path Regulator with Current Limit and OV Protection OC Comp + - + - + 4 Curr Out Diff Amp + FET Switching Ctrl Logic FETOVRD FETCTRL From Charger Detection Block Voltage Error Amp Chrg In Diff Amp BATTFET CHRGLED BP Voltage Regulator and OV Protection BP BATT BPFET BATTISNS CHRGISNSP CHRG ISNSN CHRGCTRL CHRGRAW VBUS Battery To Scaling and A/D To USB BP R2 0.1 Ω CHRGMOD1 CHRGMOD0 Vatlas M3 To Scaling and A/D BP Ref ICHRG[3:0] + - Bat In Diff Amp Trickle Charge Control 3 ICHRGTR[2:0] OC_REF + - Voltage Error Amp 3 VCHRG[2:0] To Scaling and A/D Figure 10. Serial Path Interface Block Diagram MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 37 Functional Description Table 23. Voltage and Current Settings Parameter Set Points Regulated charge voltage at BP Programmable voltage setting of 3.80/4.05/4.15/4.20/4.25/4.30/4.375/4.50V. Regulated charge current through M1M2 Programmable current from 0 to 1600 mA in 14 steps, and fully on mode. Internal trickle charge current Programmable current from 0 to 84mA in steps of 12mA. 4.4.1.2 4.4.1.2.1 Charger Operation CEA-936-A The CEA-936-A carkit specification allows a USB connection to be used not only as an USB interface but also as a generic supply plus analog audio interface. The purpose is to standardize the carkit interface over a USB connection. The USB VBUS line in this case is used to provide a supply within the USB voltage limits and with at least 500 mA of current drive capability. However, this also opens the possibility to create a range of USB compatible wall chargers, referred to as CEA-936-A charger in the remainder of this chapter. The CEA-936-A standard also allows providing a supply from the phone to the accessory over the VBUS line, just like in the USB on the go case. 4.4.1.2.2 Standalone Trickle Charging The MC13783 has a standalone trickle charge mode of operation in order to ensure that a completely discharged battery can be charged without the Microprocessor's control. Upon plugging a valid charger to the phone, the trickle cycle is started. For battery voltages below 2.7 V, the trickle charge current level is set at 70 mA. When the battery voltage increases above the threshold, the trickle charge level is increased to 266 mA. When the battery voltage rises above the threshold sufficient for phone operation, a power up sequence is automatically initiated. Even after the phone has powered up, the Standalone trickle charge will remain on until software enables charging. If the battery voltage was already greater than the voltage needed for phone operation when a charger is attached, the phone will power up immediately without starting a trickle charge cycle. The trickle charge is terminated upon charge completion, time out, or by software control. For the single path charging configuration, standalone trickle charging is only available for the SE1 = LOW condition. The charge level remains constant at the lower 70 mA threshold through all battery voltage ranges—that is, there is no increased charge current at the 2.7 V threshold. Standalone Trickle charging is not available for the SE1 = HIGH / Single Path charging case. 4.4.1.3 Coin Cell The coin cell charger circuit will function as a current-limited voltage source, resulting in the CC/CV taper characteristic typically used for rechargeable Lithium-Ion batteries. The output voltage is selectable. The coin cell charger voltage is programmable in the ON state. In the User Off modes, or in the Off state, the coincell charger will continue to charge to the predefined voltage setting but at a lower maximum current. In practice, this means that if in Off state the coin cell is fully charged, the coin cell charger will only MC13783 Technical Data, Rev. 3.5 38 Freescale Semiconductor Functional Description provide the leakage current of the coin cell. The RTC will run from VATLAS in this case. A capacitor should be placed from LICELL to ground if no coin cell is used. 4.4.2 ADC Subsystem 4.4.2.1 Converter Core The ADC core is a 10 bit successive approximation converter. 4.4.2.2 Input Selector The ADC has two groups of 8 input channels. ADSEL selects between two groups of input signals. If set to zero then group 0 is read and stored, if set to 1 then group 1 is read and stored. This is done to shorten the total read time and to reduce the required storage of converted values. The table below gives an overview of the attribution of the A to D channels. Table 24. ADC Inputs Group 1 – ADSEL=1 Group 0 – ADSEL=0 Channel Signal read Expected Input Range Scaling Scaled Version 0 Battery Voltage (BATT) 2.50 – 4.65 V - 2.40 V 0.10 – 2.25 V 1 Battery Current (BATT – BATTISNS) -50 - +50 mV x20 -1.00 - +1.00 V 2 Application Supply (BP) 2.50 – 4.65 V - 2.40 V 0.10 – 2.25 V 3 Charger Voltage (CHRGRAW) 0 – 10 V / 0 – 20 V /5 /10 0 – 2.00 V 0 – 2.00 V 4 Charger Current (CHRGISNSP-CHRGISNSN) -250mV – +250 mV X4 -1.00 – 1.00 V 5 General Purpose ADIN5 / Battery Pack Thermistor 0 – 2.30 V No 0 – 2.30 V 6 General Purpose ADIN6 / Backup Voltage (LICELL) 0 – 2.30 V / 1.50 – 3.50 V No / - 1.20 V 0 – 2.30 V 0.30 – 2.30 V 7 General Purpose ADIN7 / UID / Die Temperature 0 – 2.30 V / 0 – 2.55 V / TBD No / x0.9 / No 0 – 2.30 V 8 General Purpose ADIN8 0 - 2.30 V No 0 – 2.30 V 9 General Purpose ADIN9 0 - 2.30 V No 0 – 2.30 V 10 General Purpose ADIN10 0 - 2.30 V No 0 – 2.30 V 11 General Purpose ADIN11 0 - 2.30 V No 0 – 2.30 V 12 General Purpose TSX1 / Touchscreen X-plate 1 0 - 2.30 V No 0 – 2.30 V 13 General Purpose TSX2 / Touchscreen X-plate 2 0 - 2.30 V No 0 – 2.30 V 14 General Purpose TSY1 / Touchscreen Y-plate 1 0 - 2.30 V No 0 – 2.30 V 15 General Purpose TSY2 / Touchscreen Y-plate 2 0 - 2.30 V No 0 – 2.30 V MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 39 Functional Description 4.4.2.3 Control The ADC parameters are programmed by the processors via SPI. Locally on MC13783, the different ADC requests are arbitrated and executed. When a conversion is finished, an interrupt is generated to the processor which started the conversion. 4.4.2.3.1 Starting Conversions The ADC will have the ability to start a series of conversions based on a rising edge of the ADTRIG signal or directly initiated by SPI. Once conversion is initiated all 8 channels will be sequentially converted and stored in registers or eight conversions on one channel will be performed and stored. The conversion result can digitally be compared with respect to a preset value for threshold detection. The conversion will begin after a delay set between 0 and 8 ms. The delay between conversions can be made equal to this delay. To avoid that the ADTRIG input involuntarily triggers a conversion, a bit can be set which will make the ADC ignores any transition on the ADTRIG pin. 4.4.2.3.2 Reading Conversions Once a series of eight A/D conversions is complete, they are stored in one set of eight internal registers and the values can be read out by software. 4.4.2.4 Pulse Generator A SPI controllable pulse generator is available at ADOUT synchronized with the ADC conversion. This pulse can be used to enable or drive external circuits only during the period of 4 or 8 ADC conversions. 4.4.2.5 4.4.2.5.1 Dedicated Channels Reading Battery Current Traditional battery capacity estimation is based on battery terminal voltage reading combined with estimated phone current drain based on emitted PA power. For improved battery capacity estimation, especially in non transmit mode like gaming, this method is too approximate. To improve the estimation, the current out of the battery must be quantified more accurately. For this, on the MC13783, the current flowing out of and into the battery can be read via the ADC by monitoring the voltage drop over the sense resistor between BATT and BATTISNS. 4.4.2.5.2 Charge Current The charge current is read by monitoring the voltage drop over the charge current sense resistor. 4.4.2.5.3 Battery Thermistor If a battery is equipped with a battery thermistor, its value can be read out via the ADC input ADIN5. The biasing and sensing circuit is entirely integrated and is only powered during the A to D conversions. MC13783 Technical Data, Rev. 3.5 40 Freescale Semiconductor Functional Description 4.4.2.5.4 Die Temperature and UID The die temperature can be read out on the ADIN7 channel. Alternatively, the UID voltage can be read out on the ADIN7 channel. 4.4.2.6 Touch Screen Interface The touchscreen interface provides all circuitry required for the readout of a 4-wire resistive touchscreen. The touchscreen X plate is connected to TSX1 and TSX2 while the Y plate is connected to TSY1 and TSY2. A local supply ADREF will serve as a reference. Several readout possibilities are offered. In interrupt mode, a voltage is applied via a high impedance source to only one of the plates, the other is connected to ground. When the two plates make contact both will be at a low potential. This will generate a pen interrupt to the processor. This detection does not make use of the ADC core. A finger will connect both plates over a wider area then a stylus. To distinguish both sources, in the contact resistance mode the resistance between the plates is measured by applying a voltage difference between the X and the Y plate. The current through the plates is measured. Since the plate resistance varies from screen to screen, measuring its value will improve the pressure measurement. Also, it can help in determining if more than 1 spot is touched on the screen. In the plate measurement mode, a potential is applied across one of the plates while the other plate is left floating. The current through the plate is measured. The contact resistance mode and plate measurement mode are together referred to as resistive mode. To determine the XY coordinate pair, in position mode a voltage difference over the X plate is read out via the Y plate for the X-coordinate and vice versa for the Y- coordinate readout. In the MC13783, during the position mode the contact resistance is read as well in addition to the XY coordinate pair. To perform touchscreen readings, the processor will have to set one of the touchscreen interface readout modes, program the delay between the conversions, trigger the ADC via one of the trigger sources, wait for an interrupt indicating the conversion is done, and then read out the data. In order to reduce the interrupt rate and to allow for easier noise rejection, the touchscreen readings are repeated in the readout sequence. In this way, in total eight results are available per readout. Table 25. Touchscreen Reading Sequence ADC Trigger Signals sampled in Resistive Mode Signals sampled in Position Mode Readout Address 0 X plate resistance X position 000 1 X plate resistance X position 001 2 X plate resistance X position 010 3 Y plate resistance Y position 011 4 Y plate resistance Y position 100 5 Y plate resistance Y position 101 6 Contact resistance Contact resistance 110 7 Contact resistance Contact resistance 111 MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 41 Functional Description 4.4.2.7 ADC Arbitration The ADC converter and its control is based on a single ADC converter core. Since the data path is 24 bits wide, results for 2 conversion results (10 bits each) can be read back in each SPI read sequence. For support of queued conversion requests, the SPI has the ability to write to the two sets of ADC control, namely “its own” ADC and “the other” ADC or ADC BIS. The write access to the control of ADC BIS is handled via the ADCBISn bits located at bit position 23 of the ADC control registers. By setting this bit to a 1, the control bits which follow are directed to the ADC BIS. ADCBISn will always read back 0 and there is no read access to the ADCBIS control bits. The read results from the ADC conversions are available in two separate registers ADC result registers ADC0 and ADC1. 4.5 Miscellaneous Functions Miscellaneous functions are described in the following sections: • Section 4.5.1, “Connectivity on page 42 • Section 4.5.2, “Lighting System on page 45 4.5.1 Connectivity This section summarizes the following interface information: • Section 4.5.1.1, “USB Interface on page 42 • Section 4.5.1.2, “RS-232 Interface on page 45 • Section 4.5.1.3, “CEA-936-A Accessory Support on page 45 • Section 4.5.1.4, “Booting Support on page 45 4.5.1.1 4.5.1.1.1 USB Interface Supplies The USB interface is supplied by the VUSB (3.3 V) and the VBUS (5.0 V) regulators. The VBUS regulator takes the boost supply and regulates it down to the required USBOTG level which is provided to VBUS in the case of a USBOTG connection. The transceiver itself is supplied from VUSB. The VUSB regulator by default is supplied by BP and by SPI programming can be boost or VBUS supplied as well. 4.5.1.1.2 Detect Comparators are used to detect a valid VBUS, and to support the USB OTG session request protocol. 4.5.1.1.3 Transceiver The USB transceiver data flow is depicted in below diagram. The processor interface IO level is set to USBVCC. MC13783 Technical Data, Rev. 3.5 42 Freescale Semiconductor UDATVP UDP Tx USE0VM UDM TO ACCESSORY CONNECTOR Functional Description TO PROCESSOR Router SEO UTXENB URXVP Rx URCVD Diff URXVM Rx DATSEO, BIDIR Figure 11. USB/RS232 Transceiver Data Flow Upon a USB legacy host detection, an interrupt is generated but neither the transceiver nor the VUSB regulator are automatically enabled. This must be done by software before data transmission. The transceiver can also be enabled during boot mode. Via SPI bits DATSE0 and BIDIR, one of the four USB operating modes can be selected. However, when starting up in a boot mode, there is no up front SPI programming possible. The default operating mode is then determined by the setting of the UMOD pin as indicated in Table 26. MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 43 Functional Description Table 26. USB Mode Selection Mode Selection Mode Description USB Mode Single Ended Differential DATSE0 BIDIR 1 unidirectional (6-wire) 0 bidirectional (4-wire) unidirectional (6-wire) bidirectional (3-wire) 1 Corresponding UMOD0/UMOD1 Setting UTXENB = Low UTXENB = High 0 UDATVP → UDP USE0VM → UDM UDP → URXVP UDM → URXVM UDP/UDM → URCVD Don’t Care / To VATLAS 1 UDATVP → UDP USE0VM → UDM UDP → UDATVP UDM → USE0VM UDP/UDM → URCVD To VATLAS / To Ground 0 UDATVP→ UDP/UDM USE0VM → FSE01 UDP → URXVP UDM → URXVM UDP/UDM → URCVD To Ground / To Ground 1 UDATVP → UDP/UDM UDP/UDM → UDATVP (active) USE0VM → FSE0 UDP → UDATVP (suspend) RSE0 → USE0VM Open / To Ground FSE0 stands for forced SE0, RSE0 stands for received SE0. 4.5.1.1.4 Full Speed/ Low Speed Configuration The USB transceiver supports the low speed mode of 1.5 Mbits/second and the full speed mode of 12 Mbits/second. To indicate the speed to the host an internal 1.5 kOhm pull up to VUSB is used. Via SPI this resistor can be connected to UDP to indicate full speed, or to UDM to indicate low speed. 4.5.1.1.5 USB Suspend USB suspend mode is enabled through SPI. When set, the USB transceiver enters a low power mode which reduces the transceiver current drain to below 500 µA. In USB suspend mode, the VUSB regulator remains enabled and the VBUS detect comparators remain enabled, while the single ended receivers are switched from a comparator to a Schmitt-trigger buffer. 4.5.1.1.6 USB On-The-Go USBOTG support circuitry is added in order to allow a phone to act as a dual-role USBOTG device. In accordance with USBOTG requirements, the pull down resistors on UDP and UDM can be switched in or out individually via SPI. Furthermore, the pulls down resistors are integrated on-chip. The USBOTG specification requires that during the session request protocol, the D+ (full speed) line is pulled up for a duration of 5 to 10 msec. In order to reduce the SPI traffic, the MC13783 has an integrated timer used for this task. To support VBUS pulsing, there is a programmable current limit and timer on the VBUS regulator. During VBUS pulsing, the lower current limit allows for easier detection of a legacy host device on the far end of the USB cable. It is possible to have the transceiver automatically connect the data pull-up to VUSB any time a SE0 is detected. This enables the phone to meet the USBOTG timing requirements without unduly taxing the software. MC13783 Technical Data, Rev. 3.5 44 Freescale Semiconductor Functional Description An ID detector is used to determine if a mini-A or mini-B style plug has been inserted into a mini-AB style receptacle on the phone. The ID voltage can be read out via the ADC channel ADIN7. 4.5.1.2 RS-232 Interface In RS232 mode, USBVCC is used for the supply of the interface with the microprocessor. VUSB is used as the supply for the RS232 transceiver and the drivers at the cable side. In this mode, the USB transceiver is tri-stated and the USB module IC pins are re-used to pass the RS232 signals from the radio connector to the digital sections of the radio. Flexibility is provided for RS232 Rx and Tx signal swapping at the cable side interface pins UDP and UDM, and the possibility to enable the RS232 receiver while tri-stating the transmitter. 4.5.1.3 CEA-936-A Accessory Support Support for CEA-936-A is provided, including provision for audio muxing to UDP and UDM and ID interrupt generation. All audio path switches are residing in the USB block and are powered from the VUSB regulator. Please refer to CEA-936-A specification for details. 4.5.1.4 Booting Support The MC13783 supports booting on USB. The boot mode is entered by the USBEN pin being forced high by the booting equipment which enables the transceiver. 4.5.2 Lighting System The lighting system of MC13783 is comprised of independent controlled circuitry for backlight drivers and tri-color LED drivers. This integration provides flexible backlighting and fun lighting for products featuring multi-zone and multi-color lighting implementations. Figure 12 illustrates the lighting system utilization for a typical application. MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 45 Functional Description BOOST Key Pad BOOST Main Display Aux Display BOOST P B 1 D M D E L 2 D M D E L 3 D M D E L 4 D M D E L BL Drive Main Display 1 D A D E L 2 D A D E L BL Drive Aux Display P K D E L L B D E L D N G BL Drive Keypad 1 R D E L 1 G D E L BOOST P B 1 B D E L 2 R D E L 2 G D E L BOOST P B 2 B D E L 3 R D E L 3 G D E L 3 B D E L C T D E L D N G Tri-Color Fun Light Drive MC13783 IC Lighting System Figure 12. MC13783 Lighting System 4.5.2.1 Backlight Drivers The backlight drivers are generally intended for White LED (WLED) backlighting of color LCD displays or white/blue LED backlighting for key pads. The drivers consists of independently programmable current sinking channels. SPI registers control programmable features such as DC current level, auto ramping / dimming and PWM settings. Three zones are provided for typical applications which may include backlighting a main display, auxiliary display, and key pad. However, the drivers can be utilized for other lighting schemes such as an integrated WLED flashlight or even non-LED system applications requiring programmable current sinks. The integrated boost switcher provided on the MC13783 is used to supply the backlights. It automatically adapts its output voltage to allow for power optimized biasing of white and/or blue LEDs. Alternatively, any other available source with sufficient current drive and output voltage for necessary diode headroom may be used (5.5 V should not be exceeded). 4.5.2.2 Tri-Color LED Drivers The tri-color circuitry provides expanded capability for independent lighting control and distribution that supplements the backlight drivers circuitry. The tri-color drivers have the same basic programmability as the backlight drivers, with similar bit control for current level, duty cycle control, and ramping. A boosted MC13783 Technical Data, Rev. 3.5 46 Freescale Semiconductor Package Information supply such as the on-chip boost switcher should be used to ensure adequate headroom if necessary, such as for driving blue LEDs. The channel naming assignments are R, G, and B representative of applications which use red, green, and blue colored LEDs on each of the respective zones. One set of RGB drivers constitute a tri-color bank, and the MC13783 features three tri-color banks. Each tri-color LED driver is programmable for independent control of timing and current levels. Programmable fun light patterns are also provided to allow initiation of predefined lighting routines with convenient SPI efficiency, reducing the communication burden of running complex lighting sequences. 5 Package Information The package style is a low profile BGA, pitch 0.5 mm, body 10 × 10mm, semi populated 19 × 19 matrix, ball count 247 including 4 sets of triple corner balls and 4 spare balls. Figure 13. Package Drawing MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 47 Product Documentation 6 Product Documentation This data sheet is labeled as a particular type: Product Preview, Advance Information, or Technical Data. Definitions of these types are available at: http://www.freescale.com on the Documentation page. Table 27 summarizes revisions to this document since the previous release (Rev. 3.4). Table 27. Revision History Location Revision Table 1 Change SW3IN to HV in Table 1. Table 3 Updated consumption numbers in Table 3. Table 9 Changed VRFBG max load to 0.1mA in Table 9 Table 9 Updated loads on LDOs vs. Output voltage in table 9 Table 10 Note added in table 10 to add 3 more rows for various capacitor values. Table 4.4.1.2.2 Updated trickle levels in section 4.4.1.2.2 Table 4.4.1.2.2 Comment added to section 4.4.1.2.2: For the single path charging configuration, Standalone trickle charging is only available for the SE1 = LOW condition. The charge level remains constant at the lower 70mA threshold through all battery voltage ranges. That is, there is no increased charge current at the 2.7V threshold. Standalone Trickle charging is not available for the SE1 = HIGH / Single Path charging case. MC13783 Technical Data, Rev. 3.5 48 Freescale Semiconductor NOTES MC13783 Technical Data, Rev. 3.5 Freescale Semiconductor 49 How to Reach Us: Home Page: www.freescale.com Web Support: http://www.freescale.com/support USA/Europe or Locations Not Listed: Freescale Semiconductor Technical Information Center, EL516 2100 East Elliot Road Tempe, Arizona 85284 +1-800-521-6274 or +1-480-768-2130 www.freescale.com/support Europe, Middle East, and Africa: Freescale Halbleiter Deutschland GmbH Technical Information Center Schatzbogen 7 81829 Muenchen, Germany +44 1296 380 456 (English) +46 8 52200080 (English) +49 89 92103 559 (German) +33 1 69 35 48 48 (French) www.freescale.com/support Japan: Freescale Semiconductor Japan Ltd. Headquarters ARCO Tower 15F 1-8-1, Shimo-Meguro, Meguro-ku, Tokyo 153-0064, Japan 0120 191014 or +81 3 5437 9125 support.japan@freescale.com Information in this document is provided solely to enable system and software implementers to use Freescale Semiconductor products. There are no express or implied copyright licenses granted hereunder to design or fabricate any integrated circuits or integrated circuits based on the information in this document. Freescale Semiconductor reserves the right to make changes without further notice to any products herein. Freescale Semiconductor makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Freescale Semiconductor assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any and all liability, including without limitation consequential or incidental damages. “Typical” parameters that may be provided in Freescale Semiconductor data sheets and/or specifications can and do vary in different applications and actual performance may vary over time. All operating parameters, including “Typicals”, must be validated for each customer application by customer’s technical experts. Freescale Semiconductor does not convey any license under its patent rights nor the rights of others. Freescale Semiconductor products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the Freescale Semiconductor product could create a situation where personal injury or death may occur. Should Buyer purchase or use Freescale Semiconductor products for any such unintended or unauthorized application, Buyer shall indemnify and hold Freescale Semiconductor and its officers, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that Freescale Semiconductor was negligent regarding the design or manufacture of the part. Freescale™ and the Freescale logo are trademarks of Freescale Semiconductor, Inc. All other product or service names are the property of their respective owners. © Freescale Semiconductor, Inc. 2005, 2006, 2007, 2009. All rights reserved. Asia/Pacific: Freescale Semiconductor China Ltd. Exchange Building 23F No. 118 Jianguo Road Chaoyang District Beijing 100022 China +86 10 5879 8000 support.asia@freescale.com For Literature Requests Only: Freescale Semiconductor Literature Distribution Center 1-800-441-2447 or +1-303-675-2140 Fax: +1-303-675-2150 LDCForFreescaleSemiconductor@hibbertgroup.com Document Number: MC13783 Rev. 3.5 7/2009 RoHS-compliant and/or Pb-free versions of Freescale products have the functionality and electrical characteristics of their non-RoHS-compliant and/or non-Pb-free counterparts. For further information, see http://www.freescale.com or contact your Freescale sales representative. For information on Freescale’s Environmental Products program, go to http://www.freescale.com/epp.