Freescale Semiconductor Data Sheet: Technical Data Document Number: MC9328MXS Rev. 3, 12/2006 MC9328MXS Package Information Plastic Package Case 1304B-01 (MAPBGA–225) MC9328MXS Ordering Information See Table 1 on page 3 1 Introduction The i.MX Family of applications processors provides a leap in performance with an ARM9™ microprocessor core and highly integrated system functions. The i.MX family specifically addresses the requirements of the personal, portable product market by providing intelligent integrated peripherals, an advanced processor core, and power management capabilities. Contents 1 2 3 4 Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . 1 Signals and Connections . . . . . . . . . . . . . . . 4 Electrical Characteristics . . . . . . . . . . . . . . 16 Functional Description and Application Information . . . . . . . . . . . . . . . . . . . . . . . . . . 18 5 Pin-Out and Package Information . . . . . . . . 71 6 Product Documentation . . . . . . . . . . . . . . . . 73 Contact Information . . . . . . . . . . . . . . . Last Page The MC9328MXS (i.MXS) processor features the advanced and power-efficient ARM920T™ core that operates at speeds up to 100 MHz. Integrated modules, which include a USB device and an LCD controller, support a suite of peripherals to enhance portable products. It is packaged in a 225-contact MAPBGA package. Figure 1 shows the functional block diagram of the i.MXS processor. 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., 2006. All rights reserved. Introduction Figure 1. i.MXS Functional Block Diagram 1.1 Features To support a wide variety of applications, the processor offers a robust array of features, including the following: • • • • • • • • • • • • • • • • • • ARM920T™ Microprocessor Core AHB to IP Bus Interfaces (AIPIs) External Interface Module (EIM) SDRAM Controller (SDRAMC) DPLL Clock and Power Control Module Two Universal Asynchronous Receiver/Transmitters (UART 1 and UART 2) Serial Peripheral Interface (SPI) Two General-Purpose 32-bit Counters/Timers Watchdog Timer Real-Time Clock/Sampling Timer (RTC) LCD Controller (LCDC) Pulse-Width Modulation (PWM) Module Universal Serial Bus (USB) Device Direct Memory Access Controller (DMAC) Synchronous Serial Interface and an Inter-IC Sound (SSI/I2S) Module Inter-IC (I2C) Bus Module General-Purpose I/O (GPIO) Ports Bootstrap Mode MC9328MXS Technical Data, Rev. 3 2 Freescale Semiconductor Introduction • • • 1.2 Power Management Features Operating Voltage Range: 1.7 V to 1.9 V core, 1.7 V to 3.3 V I/O 225-contact MAPBGA Package Target Applications The i.MXS applications processor is designed to meet the needs of medical instrumentation, low-end PDAs, point-of-sale terminals, security systems and other applications requiring a basic device based on ARM technology with support for open operating systems. Like other members of the i.MX family, the i.MXS is designed for high performance and low-power to maximize battery life. 1.3 Ordering Information Table 1 provides ordering information. Table 1. i.MXS Ordering Information 1.4 Package Type Frequency Temperature Solderball Type Order Number 225-contact MAPBGA 100 MHz 0OC to 70OC Pb-free MC9328MXSVP10(R2) -40OC to 85OC Pb-free MC9328MXSCVP10(R2) Conventions This document uses the following conventions: • • • • • • • • • • • OVERBAR is used to indicate a signal that is active when pulled low: for example, RESET. Logic level one is a voltage that corresponds to Boolean true (1) state. Logic level zero is a voltage that corresponds to Boolean false (0) state. To set a bit or bits means to establish logic level one. To clear a bit or bits means to establish logic level zero. A signal is an electronic construct whose state conveys or changes in state convey information. A pin is an external physical connection. The same pin can be used to connect a number of signals. Asserted means that a discrete signal is in active logic state. — Active low signals change from logic level one to logic level zero. — Active high signals change from logic level zero to logic level one. Negated means that an asserted discrete signal changes logic state. — Active low signals change from logic level zero to logic level one. — Active high signals change from logic level one to logic level zero. LSB means least significant bit or bits, and MSB means most significant bit or bits. References to low and high bytes or words are spelled out. Numbers preceded by a percent sign (%) are binary. Numbers preceded by a dollar sign ($) or 0x are hexadecimal. MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 3 Signals and Connections 2 Signals and Connections Table 2 identifies and describes the i.MXS processor signals that are assigned to package pins. The signals are grouped by the internal module that they are connected to. Table 2. i.MXS Signal Descriptions Signal Name Function/Notes External Bus/Chip-Select (EIM) A[24:0] Address bus signals D[31:0] Data bus signals EB0 MSB Byte Strobe—Active low external enable byte signal that controls D [31:24]. EB1 Byte Strobe—Active low external enable byte signal that controls D [23:16]. EB2 Byte Strobe—Active low external enable byte signal that controls D [15:8]. EB3 LSB Byte Strobe—Active low external enable byte signal that controls D [7:0]. OE Memory Output Enable—Active low output enables external data bus. CS [5:0] Chip-Select—The chip-select signals CS [3:2] are multiplexed with CSD [1:0] and are selected by the Function Multiplexing Control Register (FMCR). By default CSD [1:0] is selected. ECB Active low input signal sent by a flash device to the EIM whenever the flash device must terminate an on-going burst sequence and initiate a new (long first access) burst sequence. LBA Active low signal sent by a flash device causing the external burst device to latch the starting burst address. BCLK (burst clock) Clock signal sent to external synchronous memories (such as burst flash) during burst mode. RW RW signal—Indicates whether external access is a read (high) or write (low) cycle. Used as a WE input signal by external DRAM. DTACK DTACK signal—The external input data acknowledge signal. When using the external DTACK signal as a data acknowledge signal, the bus time-out monitor generates a bus error when a bus cycle is not terminated by the external DTACK signal after 1022 clock counts have elapsed. Bootstrap BOOT [3:0] System Boot Mode Select—The operational system boot mode of the i.MXS processor upon system reset is determined by the settings of these pins. SDRAM Controller SDBA [4:0] SDRAM non-interleave mode bank address multiplexed with address signals A [15:11]. These signals are logically equivalent to core address p_addr [25:21] in SDRAM cycles. SDIBA [3:0] SDRAM interleave addressing mode bank address multiplexed with address signals A [19:16]. These signals are logically equivalent to core address p_addr [12:9] in SDRAM cycles. MA [11:10] SDRAM address signals MA [9:0] SDRAM address signals which are multiplexed with address signals A [10:1]. MA [9:0] are selected on SDRAM cycles. DQM [3:0] SDRAM data enable CSD0 SDRAM Chip-select signal which is multiplexed with the CS2 signal. These two signals are selectable by programming the system control register. MC9328MXS Technical Data, Rev. 3 4 Freescale Semiconductor Signals and Connections Table 2. i.MXS Signal Descriptions (Continued) Signal Name Function/Notes CSD1 SDRAM Chip-select signal which is multiplexed with CS3 signal. These two signals are selectable by programming the system control register. By default, CSD1 is selected, so it can be used as boot chip-select by properly configuring BOOT [3:0] input pins. RAS SDRAM Row Address Select signal CAS SDRAM Column Address Select signal SDWE SDRAM Write Enable signal SDCKE0 SDRAM Clock Enable 0 SDCKE1 SDRAM Clock Enable 1 SDCLK SDRAM Clock RESET_SF Not Used Clocks and Resets EXTAL16M Crystal input (4 MHz to 16 MHz), or a 16 MHz oscillator input when the internal oscillator circuit is shut down. XTAL16M Crystal output EXTAL32K 32 kHz crystal input XTAL32K 32 kHz crystal output CLKO Clock Out signal selected from internal clock signals. RESET_IN Master Reset—External active low Schmitt trigger input signal. When this signal goes active, all modules (except the reset module and the clock control module) are reset. RESET_OUT Reset Out—Internal active low output signal from the Watchdog Timer module and is asserted from the following sources: Power-on reset, External reset (RESET_IN), and Watchdog time-out. POR Power On Reset—Internal active high Schmitt trigger input signal. The POR signal is normally generated by an external RC circuit designed to detect a power-up event. JTAG TRST Test Reset Pin—External active low signal used to asynchronously initialize the JTAG controller. TDO Serial Output for test instructions and data. Changes on the falling edge of TCK. TDI Serial Input for test instructions and data. Sampled on the rising edge of TCK. TCK Test Clock to synchronize test logic and control register access through the JTAG port. TMS Test Mode Select to sequence the JTAG test controller’s state machine. Sampled on the rising edge of TCK. DMA DMA_REQ DMA Request—external DMA request signal. Multiplexed with SPI1_SPI_RDY. BIG_ENDIAN Big Endian—Input signal that determines the configuration of the external chip-select space. If it is driven logic-high at reset, the external chip-select space will be configured to big endian. If it is driven logic-low at reset, the external chip-select space will be configured to little endian. This input must not change state after power-on reset negates or during chip operation. MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 5 Signals and Connections Table 2. i.MXS Signal Descriptions (Continued) Signal Name Function/Notes ETM ETMTRACESYNC ETM sync signal which is multiplexed with A24. ETMTRACESYNC is selected in ETM mode. ETMTRACECLK ETM clock signal which is multiplexed with A23. ETMTRACECLK is selected in ETM mode. ETMPIPESTAT [2:0] ETM status signals which are multiplexed with A [22:20]. ETMPIPESTAT [2:0] are selected in ETM mode. ETMTRACEPKT [7:0] ETM packet signals which are multiplexed with ECB, LBA, BCLK (burst clock), PA17, A [19:16]. ETMTRACEPKT [7:0] are selected in ETM mode. LCD Controller LD [15:0] LCD Data Bus—All LCD signals are driven low after reset and when LCD is off. FLM/VSYNC Frame Sync or Vsync—This signal also serves as the clock signal output for the gate driver (dedicated signal SPS for Sharp panel HR-TFT). LP/HSYNC Line pulse or H sync LSCLK Shift clock ACD/OE Alternate crystal direction/output enable. CONTRAST This signal is used to control the LCD bias voltage as contrast control. SPL_SPR Program horizontal scan direction (Sharp panel dedicated signal). PS Control signal output for source driver (Sharp panel dedicated signal). CLS Start signal output for gate driver. This signal is an inverted version of PS (Sharp panel dedicated signal). REV Signal for common electrode driving signal preparation (Sharp panel dedicated signal). SPI 1 SPI1_MOSI Master Out/Slave In SPI1_MISO Slave In/Master Out SPI1_SS Slave Select (Selectable polarity) SPI1_SCLK Serial Clock SPI1_SPI_RDY Serial Data Ready General Purpose Timers TIN Timer Input Capture or Timer Input Clock—The signal on this input is applied to both timers simultaneously. TMR2OUT Timer 2 Output USB Device USBD_VMO USB Minus Output USBD_VPO USB Plus Output USBD_VM USB Minus Input USBD_VP USB Plus Input MC9328MXS Technical Data, Rev. 3 6 Freescale Semiconductor Signals and Connections Table 2. i.MXS Signal Descriptions (Continued) Signal Name Function/Notes USBD_SUSPND USB Suspend Output USBD_RCV USB Receive Data USBD_ROE USB OE USBD_AFE USB Analog Front End Enable UARTs – IrDA/Auto-Bauding UART1_RXD Receive Data UART1_TXD Transmit Data UART1_RTS Request to Send UART1_CTS Clear to Send UART2_RXD Receive Data UART2_TXD Transmit Data UART2_RTS Request to Send UART2_CTS Clear to Send UART2_DSR Data Set Ready UART2_RI Ring Indicator UART2_DCD Data Carrier Detect UART2_DTR Data Terminal Ready Serial Audio Port – SSI (configurable to I2S protocol) SSI_TXDAT Transmit Data SSI_RXDAT Receive Data SSI_TXCLK Transmit Serial Clock SSI_RXCLK Receive Serial Clock SSI_TXFS Transmit Frame Sync SSI_RXFS Receive Frame Sync I2C I2C_SCL I2C Clock I2C_SDA I2C Data PWM PWMO PWM Output Test Function TRISTATE Forces all I/O signals to high impedance for test purposes. For normal operation, terminate this input with a 1 k ohm resistor to ground. (TRI-STATE® is a registered trademark of National Semiconductor.) General Purpose Input/Output PA[14:3] Dedicated GPIO MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 7 Signals and Connections Table 2. i.MXS Signal Descriptions (Continued) Signal Name PB[13:8] Function/Notes Dedicated GPIO Digital Supply Pins NVDD Digital Supply for the I/O pins NVSS Digital Ground for the I/O pins Supply Pins – Analog Modules AVDD Supply for analog blocks Internal Power Supply QVDD Power supply pins for silicon internal circuitry QVSS Ground pins for silicon internal circuitry 2.1 I/O Pads Power Supply and Signal Multiplexing Scheme This section describes detailed information about both the power supply for each I/O pin and its function multiplexing scheme. The user can reference information provided in Table 6 on page 17 to configure the power supply scheme for each device in the system (memory and external peripherals). The function multiplexing information also shown in Table 6 allows the user to select the function of each pin by configuring the appropriate GPIO registers when those pins are multiplexed to provide different functions. Table 3. MC9328MXS Signal Multiplexing Scheme Primary I/O Supply Voltage 225 BGA Ball Signal Dir NVDD1 D2 A24 O NVDD1 C1 D31 I/O NVDD1 D1 A23 O NVDD1 E3 D30 I/O NVDD1 E2 A22 O NVDD1 E4 D29 I/O NVDD1 E1 A21 O NVDD1 F3 D28 I/O NVDD1 F1 A20 O NVDD1 F4 D27 I/O NVDD1 F2 A19 O NVDD1 G3 D26 I/O Alternate PullUp GPIO AIN BIN AOUT Default Signal Dir Mux Pull -Up ETMTRAC ESYNC O PA0 69K ETMTRAC ECLK O PA31 69K A23 ETMPIPE STAT2 O PA30 69K A22 ETMPIPE STAT1 O PA29 69K A21 ETMPIPE STAT0 O PA28 69K A20 ETMTRAC EPKT3 O PA27 69K A19 Reser ved A24 69K 69K 69K 69K 69K 69K MC9328MXS Technical Data, Rev. 3 8 Freescale Semiconductor Signals and Connections Table 3. MC9328MXS Signal Multiplexing Scheme (Continued) Primary I/O Supply Voltage 225 BGA Ball Signal Dir NVDD1 G2 A18 O NVDD1 G4 D25 I/O NVDD1 G1 A17 O NVDD1 H4 D24 I/O NVDD1 H2 A16 O NVDD1 H3 D23 I/O NVDD1 H1 A15 O NVDD1 H5 D22 I/O NVDD1 J1 A14 O NVDD1 J3 D21 I/O NVDD1 K1 A13 O NVDD1 J4 D20 I/O NVDD1 J2 A12 O NVDD1 K4 D19 I/O NVDD1 K2 A11 O NVDD1 L4 D18 I/O NVDD1 L1 A10 O NVDD1 L3 D17 I/O NVDD1 L2 A9 O NVDD1 M1 D16 I/O NVDD1 N1 A8 O NVDD1 M2 D15 I/O NVDD1 N2 A7 O NVDD1 P1 D14 I/O NVDD1 R1 A6 O NVDD1 M3 D13 I/O NVDD1 P2 A5 O NVDD1 N3 D12 I/O NVDD1 P3 A4 O NVDD1 R2 D11 I/O NVDD1 N4 EB0 O NVDD1 M4 D10 I/O NVDD1 P4 A3 O NVDD1 R3 EB1 O NVDD1 N5 D9 I/O NVDD1 R4 EB2 O Alternate PullUp GPIO AIN BIN AOUT Default Signal Dir Mux Pull -Up ETMTRAC EPKT2 O PA26 69K A18 ETMTRAC EPKT1 O PA25 69K A17 ETMTRAC EPKT0 O PA24 69K A16 69K 69K 69K 69K 69K 69K 69K 69K 69K 69K 69K 69K 69K 69K 69K 69K 69K MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 9 Signals and Connections Table 3. MC9328MXS Signal Multiplexing Scheme (Continued) Primary I/O Supply Voltage 225 BGA Ball Signal Dir NVDD1 P5 A2 O NVDD1 M5 EB3 O NVDD1 N6 D8 I/O NVDD1 R5 OE O NVDD1 P6 A1 O NVDD1 L7 CS5 O NVDD1 R6 D7 I/O NVDD1 M7 CS4 O NVDD1 R7 A0 O NVDD1 N7 CS3 O NVDD1 P7 D6 I/O NVDD1 K3 CS2 O NVDD1 R8 SDCLK O NVDD1 M8 CS1 O NVDD1 N8 CS0 O NVDD1 P8 D5 I/O NVDD1 L9 ECB I NVDD1 R9 D4 I/O NVDD1 R10 LBA O NVDD1 R11 D3 I/O NVDD1 M9 BCLK NVDD1 L8 D2 NVDD1 N9 PA17 I/O NVDD1 K10 D1 NVDD1 M10 RW I/O NVDD1 P10 MA11 O NVDD1 P9 MA10 O NVDD1 N10 D0 I/O NVDD1 R12 DQM3 O NVDD1 N11 DQM2 O NVDD1 P11 DQM1 O NVDD1 N12 DQM0 O NVDD1 P12 RAS O NVDD1 R13 CAS O NVDD1 R14 SDWE O Alternate PullUp Signal Dir GPIO AIN BIN AOUT Default Mux Pull -Up PA23 69K PA23 PA22 69K PA22 PA21 69K A0 69K 69K CSD1 CSD1 CSD0 CSD0 69K 69K ETMTRAC EPKT7 PA20 69K ECB ETMTRAC EPKT6 PA19 69K LBA ETMTRAC EPKT5 PA18 69K BCLK ETMTRAC EPKT4 PA17 69K 69K 69K 69K Reser ved DTACK PA17 69K 69K MC9328MXS Technical Data, Rev. 3 10 Freescale Semiconductor Signals and Connections Table 3. MC9328MXS Signal Multiplexing Scheme (Continued) Primary I/O Supply Voltage 225 BGA Ball Signal Dir NVDD1 N13 SDCKE0 O NVDD1 P13 SDCKE1 O NVDD1 P15 RESET_S F O NVDD1 P14 CLKO O AVDD1 R15 AVDD1 Static QVDD2 M13 QVDD2 Static AVDD1 N15 TRST I AVDD1 N14 TRISTATE I Alternate PullUp Signal Dir GPIO Mux Pull -Up PA16 69K AIN BIN AOUT Default 69K 1 AVDD1 M15 EXTAL16 M I AVDD1 L14 XTAL16M O AVDD1 L15 EXTAL32 K I AVDD1 K15 XTAL32K O AVDD1 M14 RESET_I I 69K N2 AVDD1 K14 RESET_O UT O AVDD1 L12 POR2 I AVDD1 K13 BIG_ENDI I AN3 AVDD1 M12 BOOT33 I AVDD1 K11 BOOT23 I AVDD1 J14 BOOT13 I AVDD1 J15 BOOT03 I NVDD2 J13 TDO4 O NVDD2 H15 TMS I 69K NVDD2 J12 TCK I 69K NVDD2 K12 TDI I 69K NVDD2 J11 I2C_SCL O NVDD2 H14 I2C_SDA I/O PA15 69K PA15 NVDD2 H13 Reserved I PA14 69K PA14 NVDD2 G14 Reserved I PA13 69K PA13 NVDD2 H12 Reserved I PA12 69K PA12 NVDD2 G13 Reserved I PA11 69K PA11 NVDD2 J10 Reserved I PA10 69K PA10 NVDD2 G15 Reserved I PA9 69K PA9 PA16 MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 11 Signals and Connections Table 3. MC9328MXS Signal Multiplexing Scheme (Continued) Primary Alternate GPIO I/O Supply Voltage 225 BGA Ball Signal Dir NVDD2 F15 Reserved NVDD2 G12 NVDD2 F14 NVDD2 H11 Reserved I PA5 69K PA5 NVDD2 E14 Reserved I PA4 69K PA4 NVDD2 E15 Reserved O PA3 69K PA3 NVDD2 G11 PWMO O PA2 69K PA2 AIN BIN AOUT Default Mux Pull -Up I PA8 69K PA8 Reserved I PA7 69K PA7 Reserved I PA6 69K PA6 PullUp Signal Dir NVDD2 E13 TIN I PA1 69K NVDD2 D14 TMR2OUT O PD31 69K Reserved NVDD2 F13 LD15 O PD30 69K PD30 NVDD2 F12 LD14 O PD29 69K PD29 NVDD2 D15 LD13 O PD28 69K PD28 NVDD2 C14 LD12 O PD27 69K PD27 NVDD2 D13 LD11 O PD26 69K PD26 NVDD2 E12 LD10 O PD25 69K PD25 NVDD2 C13 LD9 O PD24 69K PD24 NVDD2 C12 LD8 O PD23 69K PD23 NVDD2 B15 LD7 O PD22 69K PD22 NVDD2 B14 LD6 O PD21 69K PD21 NVDD2 A15 LD5 O PD20 69K PD20 NVDD2 A14 LD4 O PD19 69K PD19 NVDD2 B13 LD3 O PD18 69K PD18 NVDD2 A13 LD2 O PD17 69K PD17 NVDD2 D12 LD1 O PD16 69K PD16 NVDD2 B12 LD0 O PD15 69K PD15 NVDD2 C11 FLM/VSY NC O PD14 69K PD14 NVDD2 D11 LP/HSYN C O PD13 69K PD13 NVDD2 E11 ACD/OE O PD12 69K PD12 NVDD2 C10 CONTRA ST O PD11 69K PD11 NVDD2 B11 SPL_SPR O UART2_D SR O PD10 69K NVDD2 A12 PS O UART2_RI O PD9 69K NVDD2 F10 CLS O UART2_D CD O PD8 69K Reser ved PD8 NVDD2 A11 REV O UART2_D TR I PD7 69K Reser ved PD7 Reser ved PA1 PD31 Reser ved PD10 Reserved PD9 MC9328MXS Technical Data, Rev. 3 12 Freescale Semiconductor Signals and Connections Table 3. MC9328MXS Signal Multiplexing Scheme (Continued) Primary I/O Supply Voltage 225 BGA Ball Signal Dir NVDD2 B10 LSCLK NVDD3 D10 NVDD3 E10 Alternate GPIO AIN BIN AOUT Default Mux Pull -Up O PD6 69K PD6 SPI1_MO SI I/O PC17 69K PC17 SPI1_MIS O I/O PC16 69K PC16 PullUp Signal Dir NVDD3 B9 SPI1_SS I/O PC15 69K PC15 NVDD3 A10 SPI1_SCL K I/O PC14 69K PC14 NVDD3 A9 SPI1_SPI _RDY I/O PC13 69K NVDD3 E8 UART1_R XD I PC12 69K PC12 NVDD3 B8 UART1_T XD O PC11 69K PC11 NVDD3 C9 UART1_R TS I PC10 69K PC10 NVDD3 E9 UART1_C TS O PC9 69K PC9 NVDD3 A8 SSI_TXCL K I/O PC8 69K PC8 NVDD3 C8 SSI_TXFS I/O PC7 69K PC7 NVDD3 F9 SSI_TXDA T O PC6 69K PC6 NVDD3 B7 SSI_RXD AT I PC5 69K PC5 NVDD3 F8 SSI_RXCL K I PC4 69K PC4 NVDD3 A7 SSI_RXFS I PC3 69K PC3 NVDD4 C7 UART2_R XD I PB31 69K PB31 NVDD4 D8 UART2_T XD O PB30 69K PB30 NVDD4 E7 UART2_R TS I PB29 69K PB29 NVDD4 F7 UART2_C TS O PB28 69K PB28 NVDD4 B6 USBD_VM O O PB27 69K PB27 NVDD4 C6 USBD_VP O O PB26 69K PB26 NVDD4 A6 USBD_VM I PB25 69K PB25 NVDD4 D6 USBD_VP I PB24 69K PB24 NVDD4 A5 USBD_SU SPND O PB23 69K PB23 DMA_REQ PC13 MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 13 Signals and Connections Table 3. MC9328MXS Signal Multiplexing Scheme (Continued) I/O Supply Voltage 225 BGA Ball NVDD4 Primary Alternate GPIO AIN BIN AOUT Default Mux Pull -Up I/O PB22 69K PB22 USBD_RO E O PB21 69K PB21 B4 USBD_AF E O PB20 69K PB20 NVDD4 A3 PB19 I/O 69K PB19 NVDD4 C4 PB18 I/O 69K PB18 NVDD4 D4 PB17 O 69K PB17 NVDD4 B3 PB16 I 69K PB16 NVDD4 A2 PB15 I 69K PB15 NVDD4 C3 PB14 I 69K PB14 NVDD4 A1 Reserved I/O Reserved PB13 69K PB13 NVDD4 B2 Reserved O Reserved PB12 69K PB12 NVDD4 B1 Reserved I/O Reserved PB11 69K (pull down) PB11 NVDD4 C5 Reserved I/O Reserved PB10 69K PB10 NVDD4 D3 Reserved I/O Reserved PB9 69K PB9 NVDD4 C2 Reserved I/O Reserved PB8 69K PB8 NVDD1 D5 NVDD1 Static G6 NVSS Static Signal Dir B5 USBD_RC V NVDD4 A4 NVDD4 NVDD1 QVDD1 NVDD1 NVDD1 NVDD1 NVDD1 NVDD1 NVDD1 E5 NVDD1 Static H6 NVSS Static J8 QVDD1 Static E6 QVSS Static F5 NVDD Static J6 NVSS Static G5 NVDD1 Static K6 NVSS Static J5 NVDD1 Static H7 NVSS Static K5 NVDD1 Static J7 NVSS Static L5 NVDD1 Static G8 NVSS Static L5 NVDD1 Static H8 NVSS Static K7 QVSS Static PullUp Signal Dir MC9328MXS Technical Data, Rev. 3 14 Freescale Semiconductor Signals and Connections Table 3. MC9328MXS Signal Multiplexing Scheme (Continued) Primary I/O Supply Voltage 225 BGA Ball Signal Dir NVDD2 H10 NVDD2 Static G9 NVSS Static F11 QVDD3 Static G10 QVSS Static C15 NVDD2 Static H9 NVSS Static D7 QVDD4 Static L13 QVSS Static D9 NVDD3 Static J9 NVSS Static K9 NVSS Static QVDD3 NVDD2 QVDD4 NVDD3 NVDD4 G7 NVDD4 Static NVDD1 F6 NVDD1 Static NVDD1 L6 NVDD1 Static NVDD1 M6 NVDD1 Static NVDD1 K8 NVDD1 Static L10 NVSS Static L11 NVSS Static M11 NVSS Static Alternate PullUp Signal Dir GPIO Mux Pull -Up AIN BIN AOUT Default 1 Pull down this input with 1KΩ resistor to GND. External circuit required to drive this input. 3 Tie this input high (to AVDD) or pull down with 1KΩ resistor to GND. 4 Pull up this output with a resistor to NVDD2. 2 MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 15 Electrical Characteristics 3 Electrical Characteristics This section contains the electrical specifications and timing diagrams for the i.MXS processor. 3.1 Maximum Ratings Table 4 provides information on maximum ratings which are those values beyond which damage to the device may occur. Functional operation should be restricted to the limits listed in Recommended Operating Range Table 5 on page 17 or the DC Characteristics table. Table 4. Maximum Ratings Symbol Rating Minimum Maximum Unit NVDD DC I/O Supply Voltage -0.3 3.3 V QVDD DC Internal (core = 100 MHz) Supply Voltage -0.3 1.9 V AVDD DC Analog Supply Voltage -0.3 3.3 V DC Bluetooth Supply Voltage -0.3 3.3 V BTRFVDD VESD_HBM ESD immunity with HBM (human body model) – 2000 V VESD_MM ESD immunity with MM (machine model) – 100 V Latch-up immunity – 200 mA ILatchup Test Storage temperature -55 150 °C Pmax Power Consumption 8001 13002 mW 1 A typical application with 30 pads simultaneously switching assumes the GPIO toggling and instruction fetches from the ARM® core-that is, 7x GPIO, 15x Data bus, and 8x Address bus. 2 A worst-case application with 70 pads simultaneously switching assumes the GPIO toggling and instruction fetches from the ARM core-that is, 32x GPIO, 30x Data bus, 8x Address bus. These calculations are based on the core running its heaviest OS application at 100MHz, and where the whole image is running out of SDRAM. QVDD at 1.9V, NVDD and AVDD at 3.3V, therefore, 180mA is the worst measurement recorded in the factory environment, max 5mA is consumed for OSC pads, with each toggle GPIO consuming 4mA. 3.2 Recommended Operating Range Table 5 provides the recommended operating ranges for the supply voltages and temperatures. The i.MXS processor has multiple pairs of VDD and VSS power supply and return pins. QVDD and QVSS pins are used for internal logic. All other VDD and VSS pins are for the I/O pads voltage supply, and each pair of VDD and VSS provides power to the enclosed I/O pads. This design allows different peripheral supply voltage levels in a system. Because AVDD pins are supply voltages to the analog pads, it is recommended to isolate and noise-filter the AVDD pins from other VDD pins. For more information about I/O pads grouping per VDD, please refer to Table 2 on page 4. MC9328MXS Technical Data, Rev. 3 16 Freescale Semiconductor Electrical Characteristics Table 5. Recommended Operating Range Symbol Rating Minimum Maximum Unit TA Operating temperature range MC9328MXSVP10 0 70 °C TA Operating temperature range MC9328MXSCVP10 -40 85 °C NVDD I/O supply voltage (if using SPI, LCD, and USBd which are only 3 V interfaces) 2.70 3.30 V NVDD I/O supply voltage (if not using the peripherals listed above) 1.70 3.30 V QVDD Internal supply voltage (Core = 100 MHz) 1.70 1.90 V AVDD Analog supply voltage 1.70 3.30 V 3.3 Power Sequence Requirements For required power-up and power-down sequencing, please refer to the “Power-Up Sequence” section of application note AN2537 on the i.MX applications processor website. 3.4 DC Electrical Characteristics Table 6 contains both maximum and minimum DC characteristics of the i.MXS processor. Table 6. Maximum and Minimum DC Characteristics Number or Symbol Min Typical Max Unit Full running operating current at 1.8V for QVDD, 3.3V for NVDD/AVDD (Core = 96 MHz, System = 96 MHz, driving TFT display panel, and OS with MMU enabled memory system is running on external SDRAM). – QVDD at 1.8V = 120mA; NVDD+AVDD at 3.0V = 30mA – mA Sidd1 Standby current (Core = 100 MHz, QVDD = 1.8V, temp = 25°C) – 25 – μA Sidd2 Standby current (Core = 100 MHz, QVDD = 1.8V, temp = 55°C) – 45 – μA Sidd3 Standby current (Core = 100 MHz, QVDD = 1.9V, temp = 25°C) – 35 – μA Sidd4 Standby current (Core = 100 MHz, QVDD = 1.9V, temp = 55°C) – 60 – μA Iop Parameter VIH Input high voltage 0.7VDD – Vdd+0.2 V VIL Input low voltage – – 0.4 V VOH Output high voltage (IOH = 2.0 mA) 0.7VDD – Vdd V VOL Output low voltage (IOL = -2.5 mA) – – 0.4 V Input low leakage current (VIN = GND, no pull-up or pull-down) – – ±1 μA IIL MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 17 Functional Description and Application Information Table 6. Maximum and Minimum DC Characteristics (Continued) Number or Symbol Parameter Min Typical Max Unit – – ±1 μA IIH Input high leakage current (VIN = VDD, no pull-up or pull-down) IOH Output high current (VOH = 0.8VDD, VDD = 1.8V) 4.0 – – mA IOL Output low current (VOL = 0.4V, VDD = 1.8V) -4.0 – – mA IOZ Output leakage current (Vout = VDD, output is high impedance) – – ±5 μA Ci Input capacitance – – 5 pF Co Output capacitance – – 5 pF 3.5 AC Electrical Characteristics The AC characteristics consist of output delays, input setup and hold times, and signal skew times. All signals are specified relative to an appropriate edge of other signals. All timing specifications are specified at a system operating frequency from 0 MHz to 96 MHz (core operating frequency 100 MHz) with an operating supply voltage from VDD min to VDD max under an operating temperature from TL to TH. All timing is measured at 30 pF loading. Table 7. Tristate Signal Timing Pin TRISTATE Parameter Minimum Maximum Unit – 20.8 ns Time from TRISTATE activate until I/O becomes Hi-Z Table 8. 32k/16M Oscillator Signal Timing Parameter EXTAL32k input jitter (peak to peak) EXTAL32k startup time EXTAL16M input jitter (peak to peak) 1 EXTAL16M startup time 1 1 4 Minimum RMS Maximum Unit – 5 20 ns 800 – – ms – TBD TBD – TBD – – – The 16 MHz oscillator is not recommended for use in new designs. Functional Description and Application Information This section provides the electrical information including and timing diagrams for the individual modules of the i.MXS. MC9328MXS Technical Data, Rev. 3 18 Freescale Semiconductor Functional Description and Application Information 4.1 Embedded Trace Macrocell All registers in the ETM9 are programmed through a JTAG interface. The interface is an extension of the ARM920T processor’s TAP controller, and is assigned scan chain 6. The scan chain consists of a 40-bit shift register comprised of the following: • 32-bit data field • 7-bit address field • A read/write bit The data to be written is scanned into the 32-bit data field, the address of the register into the 7-bit address field, and a 1 into the read/write bit. A register is read by scanning its address into the address field and a 0 into the read/write bit. The 32-bit data field is ignored. A read or a write takes place when the TAP controller enters the UPDATE-DR state. The timing diagram for the ETM9 is shown in Figure 2. See Table 9 for the ETM9 timing parameters used in Figure 2. 2a 1 2b 3a TRACECLK 3b TRACECLK (Half-Rate Clocking Mode) Valid Data Output Trace Port Valid Data 4a 4b Figure 2. Trace Port Timing Diagram Table 9. Trace Port Timing Diagram Parameter Table 1.8 ± 0.1 V Ref No. 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum 1 CLK frequency 0 85 0 100 MHz 2a Clock high time 1.3 – 2 – ns 2b Clock low time 3 – 2 – ns 3a Clock rise time – 4 – 3 ns 3b Clock fall time – 3 – 3 ns 4a Output hold time 2.28 – 2 – ns 4b Output setup time 3.42 – 3 – ns MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 19 Functional Description and Application Information 4.2 DPLL Timing Specifications Parameters of the DPLL are given in Table 10. In this table, Tref is a reference clock period after the pre-divider and Tdck is the output double clock period. Table 10. DPLL Specifications Parameter Test Conditions Minimum Typical Maximum Unit 5 – 100 MHz 5 – 30 MHz DPLL input clock freq range Vcc = 1.8V Pre-divider output clock freq range Vcc = 1.8V DPLL output clock freq range Vcc = 1.8V 80 – 220 MHz Pre-divider factor (PD) – 1 – 16 – Total multiplication factor (MF) Includes both integer and fractional parts 5 – 15 – MF integer part – 5 – 15 – MF numerator Should be less than the denominator 0 – 1022 – MF denominator – 1 – 1023 – Pre-multiplier lock-in time – – – 312.5 μsec Freq lock-in time after full reset FOL mode for non-integer MF (does not include pre-multi lock-in time) 250 280 (56 μs) 300 Tref Freq lock-in time after partial reset FOL mode for non-integer MF (does not include pre-multi lock-in time) 220 250 (50 μs) 270 Tref Phase lock-in time after full reset FPL mode and integer MF (does not include pre-multi lock-in time) 300 350 (70 μs) 400 Tref Phase lock-in time after partial reset FPL mode and integer MF (does not include pre-multi lock-in time) 270 320 (64 μs) 370 Tref Freq jitter (p-p) – – 0.005 (0.01%) 0.01 2•Tdck Phase jitter (p-p) Integer MF, FPL mode, Vcc=1.8V – 1.0 (10%) 1.5 ns Power supply voltage – 1.7 – 2.5 V Power dissipation FOL mode, integer MF, fdck = 100 MHz, Vcc = 1.8V – – 4 mW 4.3 Reset Module The timing relationships of the Reset module with the POR and RESET_IN are shown in Figure 3 and Figure 4. NOTE Be aware that NVDD must ramp up to at least 1.8V before QVDD is powered up to prevent forward biasing. MC9328MXS Technical Data, Rev. 3 20 Freescale Semiconductor Functional Description and Application Information 90% AVDD 1 10% AVDD POR 2 RESET_POR Exact 300ms 3 7 cycles @ CLK32 RESET_DRAM 4 HRESET 14 cycles @ CLK32 RESET_OUT CLK32 HCLK Figure 3. Timing Relationship with POR 5 RESET_IN 14 cycles @ CLK32 HRESET RESET_OUT 4 6 CLK32 HCLK Figure 4. Timing Relationship with RESET_IN MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 21 Functional Description and Application Information Table 11. Reset Module Timing Parameter Table Ref No. 1 1.8 ± 0.1 V 3.0 ± 0.3 V Parameter Unit Min Max Min Max note1 – note1 – – 300 300 300 300 ms 1 Width of input POWER_ON_RESET 2 Width of internal POWER_ON_RESET (CLK32 at 32 kHz) 3 7K to 32K-cycle stretcher for SDRAM reset 7 7 7 7 Cycles of CLK32 4 14K to 32K-cycle stretcher for internal system reset HRESERT and output reset at pin RESET_OUT 14 14 14 14 Cycles of CLK32 5 Width of external hard-reset RESET_IN 4 – 4 – Cycles of CLK32 6 4K to 32K-cycle qualifier 4 4 4 4 Cycles of CLK32 POR width is dependent on the 32 or 32.768 kHz crystal oscillator start-up time. Design margin should allow for crystal tolerance, i.MX chip variations, temperature impact, and supply voltage influence. Through the process of supplying crystals for use with CMOS oscillators, crystal manufacturers have developed a working knowledge of start-up time of their crystals. Typically, start-up times range from 400 ms to 1.2 seconds for this type of crystal. If an external stable clock source (already running) is used instead of a crystal, the width of POR should be ignored in calculating timing for the start-up process. 4.4 External Interface Module The External Interface Module (EIM) handles the interface to devices external to the i.MXS processor, including the generation of chip-selects for external peripherals and memory. The timing diagram for the EIM is shown in Figure 5, and Table 12 defines the parameters of signals. MC9328MXS Technical Data, Rev. 3 22 Freescale Semiconductor Functional Description and Application Information (HCLK) Bus Clock 1a 1b 2a 2b 3a 3b Address Chip-select Read (Write) 4a OE (rising edge) 4b 4c OE (falling edge) 4d 5a EB (rising edge) 5b 5c EB (falling edge) 5d 6a LBA (negated falling edge) 6b 6a LBA (negated rising edge) 6c 7a BCLK (burst clock) - rising edge 7b 7c 7d BCLK (burst clock) - falling edge 8b Read Data 9a 8a 9b Write Data (negated falling) 9a 9c Write Data (negated rising) 10a DTACK_B 10a Figure 5. EIM Bus Timing Diagram Table 12. EIM Bus Timing Parameter Table 1.8 ± 0.1 V Ref No. 3.0 ± 0.3 V Parameter Unit Min Typical Max Min Typical Max 1a Clock fall to address valid 2.48 3.31 9.11 2.4 3.2 8.8 ns 1b Clock fall to address invalid 1.55 2.48 5.69 1.5 2.4 5.5 ns 2a Clock fall to chip-select valid 2.69 3.31 7.87 2.6 3.2 7.6 ns 2b Clock fall to chip-select invalid 1.55 2.48 6.31 1.5 2.4 6.1 ns 3a Clock fall to Read (Write) Valid 1.35 2.79 6.52 1.3 2.7 6.3 ns 3b Clock fall to Read (Write) Invalid 1.86 2.59 6.11 1.8 2.5 5.9 ns MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 23 Functional Description and Application Information Table 12. EIM Bus Timing Parameter Table (Continued) 1.8 ± 0.1 V Ref No. 4a Unit Clock1 rise to Output Enable Valid 1 Min Typical Max Min Typical Max 2.32 2.62 6.85 2.3 2.6 6.8 ns 4b Clock rise to Output Enable Invalid 2.11 2.52 6.55 2.1 2.5 6.5 ns 4c Clock1 fall to Output Enable Valid 2.38 2.69 7.04 2.3 2.6 6.8 ns 1 4d Clock fall to Output Enable Invalid 2.17 2.59 6.73 2.1 2.5 6.5 ns 5a Clock1 rise to Enable Bytes Valid 1.91 2.52 5.54 1.9 2.5 5.5 ns 1 5b Clock rise to Enable Bytes Invalid 1.81 2.42 5.24 1.8 2.4 5.2 ns 5c Clock1 fall to Enable Bytes Valid 1.97 2.59 5.69 1.9 2.5 5.5 ns 5d Clock1 1.76 2.48 5.38 1.7 2.4 5.2 ns 6a Clock1 fall to Load Burst Address Valid 2.07 2.79 6.73 2.0 2.7 6.5 ns 6b Clock1 1.97 2.79 6.83 1.9 2.7 6.6 ns 6c Clock1 rise to Load Burst Address Invalid 1.91 2.62 6.45 1.9 2.6 6.4 ns 7a Clock1 1.61 2.62 5.64 1.6 2.6 5.6 ns 7b Clock1rise to Burst Clock fall 1.61 2.62 5.84 1.6 2.6 5.8 ns 7c Clock1 1.55 2.48 5.59 1.5 2.4 5.4 ns 7d Clock1 fall to Burst Clock fall 1.55 2.59 5.80 1.5 2.5 5.6 ns 8a Read Data setup time 5.54 – – 5.5 – – ns 8b Read Data hold time 0 – – 0 – – ns 9a Clock1 1.81 2.72 6.85 1.8 2.7 6.8 ns 9b Clock1 fall to Write Data Invalid 1.45 2.48 5.69 1.4 2.4 5.5 ns 9c Clock1 1.63 – – 1.62 – – ns 2.52 – – 2.5 – – ns 10a 1 3.0 ± 0.3 V Parameter fall to Enable Bytes Invalid fall to Load Burst Address Invalid rise to Burst Clock rise fall to Burst Clock rise rise to Write Data Valid rise to Write Data Invalid DTACK setup time Clock refers to the system clock signal, HCLK, generated from the System DPLL 4.4.1 DTACK Signal Description The DTACK signal is the external input data acknowledge signal. When using the external DTACK signal as a data acknowledge signal, the bus time-out monitor generates a bus error when a bus cycle is not terminated by the external DTACK signal after 1022 HCLK counts have elapsed. Only the CS5 group supports DTACK signal function when the external DTACK signal is used for data acknowledgement. 4.4.2 DTACK Signal Timing Figure 6 through Figure 9 show the access cycle timing used by chip-select 5. The signal values and units of measure for this figure are found in the associated tables. MC9328MXS Technical Data, Rev. 3 24 Freescale Semiconductor Functional Description and Application Information 4.4.2.1 WAIT Read Cycle without DMA 3 Address 2 8 CS5 1 9 programmable min 0ns EB 5 OE 4 WAIT 7 DATABUS (input to i.MXS) 10 6 11 Figure 6. WAIT Read Cycle without DMA Table 13. WAIT Read Cycle without DMA: WSC = 111111, DTACK_SEL=1, HCLK=96MHz 3.0 ± 0.3 V Number Characteristic Unit Minimum Maximum See note 2 – ns 3T – ns 1 OE and EB assertion time 2 CS5 pulse width 3 OE negated to address inactive 56.81 57.28 ns 4 Wait asserted after OE asserted – 1020T ns 5 Wait asserted to OE negated 2T+1.57 3T+7.33 ns 6 Data hold timing after OE negated T-1.49 – ns 7 Data ready after wait asserted 0 T ns 8 OE negated to CS negated 1.5T-0.68 1.5T-0.06 ns 9 OE negated after EB negated 0.06 0.18 ns 10 Become low after CS5 asserted 0 1019T ns 11 Wait pulse width 1T 1020T ns Note: 1. T is the system clock period. (For 96 MHz system clock, T=10.42 ns) 2. OE and EB assertion time is programmable by OEA bit in CS5L register. EB assertion in read cycle will occur only when EBC bit in CS5L register is clear. 3. Address becomes valid and CS asserts at the start of read access cycle. 4. The external wait input requirement is eliminated when CS5 is programmed to use internal wait state. MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 25 Functional Description and Application Information 4.4.2.2 WAIT Read Cycle DMA Enabled 4 Address 2 9 CS5 1 EB 10 programmable min 0ns 3 6 OE RW (logic high) 5 WAIT 7 11 S 8 DATABUS 12 Figure 7. DTACK WAIT Read Cycle DMA Enabled Table 14. DTACK WAIT Read Cycle DMA Enabled: WSC = 111111, DTACK_SEL=1, HCLK=96MHz 3.0 ± 0.3 V Number Characteristic Unit Minimum Maximum See note 2 – ns 3T – ns 1.5T-0.68 1.5T-0.06 ns 1 OE and EB assertion time 2 CS pulse width 3 OE negated before CS5 is negated 4 Address inactived before CS negated – 0.05 ns 5 Wait asserted after CS5 asserted – 1020T ns 6 Wait asserted to OE negated 2T+1.57 3T+7.33 ns 7 Data hold timing after OE negated T-1.49 – ns 8 Data ready after wait is asserted – T ns 9 CS deactive to next CS active T – ns 10 OE negate after EB negate 0.06 0.18 ns 11 Wait becomes low after CS5 asserted 0 1019T ns MC9328MXS Technical Data, Rev. 3 26 Freescale Semiconductor Functional Description and Application Information Table 14. DTACK WAIT Read Cycle DMA Enabled: WSC = 111111, DTACK_SEL=1, HCLK=96MHz (Continued) 3.0 ± 0.3 V Number 12 Characteristic Unit Minimum Maximum 1T 1020T Wait pulse width ns Note: 1. T is the system clock period. (For 96 MHz system clock, T=10.42 ns) 2. OE and EB assertion time is programmable by OEA bit in CS5L register. EB assertion in read cycle will occur only when EBC bit in CS5L register is clear. 3. Address becomes valid and CS asserts at the start of read access cycle. 4. The external wait input requirement is eliminated when CS5 is programmed to use internal wait state. 4.4.2.3 WAIT Write Cycle without DMA 5 Address 1 3 programmable min 0ns CS5 2 10 programmable min 0ns EB 4 7 RW OE (logic high) 6 WAIT DATABUS from i.MXS 11 9 8 12 Figure 8. WAIT Write Cycle without DMA Table 15. WAIT Write Cycle without DMA: WSC = 111111, DTACK_SEL=1, HCLK=96MHz 3.0 ± 0.3 V Number Characteristic Unit Minimum Maximum 1 CS5 assertion time See note 2 – ns 2 EB assertion time See note 2 – ns 3 CS5 pulse width 3T – ns 4 RW negated before CS5 is negated 2.5T-3.63 2.5T-1.16 ns 5 RW negated to Address inactive 64.22 – ns 6 Wait asserted after CS5 asserted – 1020T ns MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 27 Functional Description and Application Information Table 15. WAIT Write Cycle without DMA: WSC = 111111, DTACK_SEL=1, HCLK=96MHz (Continued) 3.0 ± 0.3 V Number Characteristic Unit Minimum Maximum 7 Wait asserted to RW negated T+2.66 2T+7.96 ns 8 Data hold timing after RW negated 2T+0.03 – ns 9 Data ready after CS5 is asserted – T ns 10 EB negated after CS5 is negated 0.5T 0.5T+0.5 ns 11 Wait becomes low after CS5 asserted 0 1019T ns 12 Wait pulse width 1T 1020T ns Note: 1. T is the system clock period. (For 96 MHz system clock, T=10.42 ns) 2. CS5 assertion can be controlled by CSA bits. EB assertion can also be programmable by WEA bits in CS5L register. 3. Address becomes valid and RW asserts at the start of write access cycle. 4. The external wait input requirement is eliminated when CS5 is programmed to use internal wait state. 4.4.2.4 WAIT Write Cycle DMA Enabled 5 Address 1 CS5 3 programmable min 0ns 10 2 EB 11 programmable min 0ns 7 4 RW 6 OE (logic high) 12 WAIT 9 13 8 DATABUS S Figure 9. WAIT Write Cycle DMA Enabled MC9328MXS Technical Data, Rev. 3 28 Freescale Semiconductor Functional Description and Application Information Table 16. WAIT Write Cycle DMA Enabled: WSC = 111111, DTACK_SEL=1, HCLK=96MHz 3.0 ± 0.3 V Number Characteristic Unit Minimum Maximum 1 CS5 assertion time See note 2 – ns 2 EB assertion time See note 2 – ns 3 CS5 pulse width 3T – ns 4 RW negated before CS5 is negated 2.5T-3.63 2.5T-1.16 ns 5 Address inactived after CS negated – 0.09 ns 6 Wait asserted after CS5 asserted – 1020T ns 7 Wait asserted to RW negated T+2.66 2T+7.96 ns 8 Data hold timing after RW negated 2T+0.03 – ns 9 Data ready after CS5 is asserted – T ns 10 CS deactive to next CS active T – ns 11 EB negate after CS negate 0.5T 0.5T+0.5 12 Wait becomes low after CS5 asserted 0 1019T ns 13 Wait pulse width 1T 1020T ns Note: 1. T is the system clock period. (For 96 MHz system clock, T=10.42 ns) 2. CS5 assertion can be controlled by CSA bits. EB assertion also can be programmable by WEA bits in CS5L register. 3. Address becomes valid and RW asserts at the start of write access cycle. 4.The external wait input requirement is eliminated when CS5 is programmed to use internal wait state. 4.4.3 EIM External Bus Timing The External Interface Module (EIM) is the interface to devices external to the i.MXS, including generation of chip-selects for external peripherals and memory. The timing diagram for the EIM is shown in Figure 5, and Table 12 defines the parameters of signals. MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 29 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[0] htrans Seq/Nonseq hwrite Read haddr V1 hready weim_hrdata Last Valid Data V1 weim_hready BCLK (burst clock) ADDR Last Valid Address V1 CS2 R/W Read LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA V1 Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 10. WSC = 1, A.HALF/E.HALF MC9328MXS Technical Data, Rev. 3 30 Freescale Semiconductor Functional Description and Application Information hclk Internal signals - shown only for illustrative purposes hsel_weim_cs[0] htrans Nonseq hwrite Write haddr V1 hready hwdata Last Valid Data weim_hrdata Write Data (V1) Unknown Last Valid Data weim_hready BCLK (burst clock) ADDR Last Valid Address V1 CS0 R/W Write LBA OE EB DATA Last Valid Data Write Data (V1) Figure 11. WSC = 1, WEA = 1, WEN = 1, A.HALF/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 31 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[0] htrans Nonseq hwrite Read haddr V1 hready weim_hrdata Last Valid Data V1 Word weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V1 + 2 CS0 R/W Read LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA 1/2 Half Word 2/2 Half Word Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 12. WSC = 1, OEA = 1, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 32 Freescale Semiconductor Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[0] htrans Nonseq hwrite Write haddr V1 hready hwdata Last Valid Data Write Data (V1 Word) weim_hrdata Last Valid Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 + 2 Address V1 CS0 R/W Write LBA OE EB DATA 1/2 Half Word 2/2 Half Word Figure 13. WSC = 1, WEA = 1, WEN = 2, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 33 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[3] htrans Nonseq hwrite Read haddr V1 hready weim_hrdata Last Valid Data V1 Word weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V1 + 2 CS[3] R/W Read LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA 1/2 Half Word 2/2 Half Word Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 14. WSC = 3, OEA = 2, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 34 Freescale Semiconductor Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[3] htrans Nonseq hwrite Write haddr V1 hready hwdata Last Valid Data Write Data (V1 Word) weim_hrdata Last Valid Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V1 + 2 CS3 Write R/W LBA OE EB DATA Last Valid Data 1/2 Half Word 2/2 Half Word Figure 15. WSC = 3, WEA = 1, WEN = 3, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 35 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq hwrite Read haddr V1 hready weim_hrdata Last Valid Data V1 Word weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 + 2 Address V1 CS2 R/W Read LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) weim_data_in 1/2 Half Word 2/2 Half Word Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 16. WSC = 3, OEA = 4, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 36 Freescale Semiconductor Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq hwrite Write haddr V1 hready Valid hwdata Last Data Write Data (V1 Word) weim_hrdata Last Valid Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V1 + 2 CS2 R/W Write LBA OE EB DATA Last Valid Data 1/2 Half Word 2/2 Half Word Figure 17. WSC = 3, WEA = 2, WEN = 3, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 37 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq hwrite Read haddr V1 hready weim_hrdata Last Valid Data V1 Word weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V1 + 2 CS2 Read R/W LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA 1/2 Half Word 2/2 Half Word Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 18. WSC = 3, OEN = 2, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 38 Freescale Semiconductor Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq hwrite Read haddr V1 hready weim_hrdata V1 Word Last Valid Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V1 + 2 CS2 R/W Read LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA 1/2 Half Word 2/2 Half Word Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 19. WSC = 3, OEA = 2, OEN = 2, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 39 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq hwrite Write haddr V1 hready hwdata Last Valid Data Write Data (V1 Word) weim_hrdata Unknown Last Valid Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V1 + 2 CS2 R/W Write LBA OE EB DATA Last Valid Data 1/2 Half Word 2/2 Half Word Figure 20. WSC = 2, WWS = 1, WEA = 1, WEN = 2, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 40 Freescale Semiconductor Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq hwrite Write haddr V1 hready Valid hwdata Last Data Unknown Write Data (V1 Word) weim_hrdata Last Valid Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V1 + 2 CS2 R/W Write LBA OE EB DATA Last Valid Data 1/2 Half Word 2/2 Half Word Figure 21. WSC = 1, WWS = 2, WEA = 1, WEN = 2, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 41 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq Nonseq hwrite Read Write haddr V1 V8 hready hwdata weim_hrdata Last Valid Data Write Data Last Valid Data Read Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V8 CS2 R/W Write Read LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA DATA Read Data Last Valid Data Write Data Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 22. WSC = 2, WWS = 2, WEA = 1, WEN = 2, A.HALF/E.HALF MC9328MXS Technical Data, Rev. 3 42 Freescale Semiconductor Functional Description and Application Information Read Idle Write Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq Nonseq hwrite Read Write haddr V1 V8 hready hwdata weim_hrdata Write Data Last Valid Data Last Valid Data Read Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V8 CS2 R/W Read Write LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA DATA Read Data Last Valid Data Write Data Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 23. WSC = 2, WWS = 1, WEA = 1, WEN = 2, EDC = 1, A.HALF/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 43 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[4] htrans Nonseq hwrite Write haddr V1 hready hwdata Last Valid Data Write Data (Word) weim_hrdata Last Valid Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V1 + 2 CS R/W Write LBA OE EB DATA Last Valid Data Write Data (1/2 Half Word) Write Data (2/2 Half Word) Figure 24. WSC = 2, CSA = 1, WWS = 1, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 44 Freescale Semiconductor Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[4] htrans Nonseq Nonseq hwrite Read Write haddr V1 V8 hready hwdata weim_hrdata Last Valid Data Write Data Last Valid Data Read Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V8 CS4 R/W Write Read LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA DATA Read Data Last Valid Data Write Data Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 25. WSC = 3, CSA = 1, A.HALF/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 45 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[4] htrans Nonseq hwrite Read Read haddr V1 V2 Idle Seq hready weim_hrdata Last Valid Data Read Data (V1) Read Data (V2) weim_hready BCLK (burst clock) ADDR Last Valid Address V1 Address V2 CNC CS4 Read R/W LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA Read Data (V1) Read Data (V2) Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 26. WSC = 2, OEA = 2, CNC = 3, BCM = 1, A.HALF/E.HALF MC9328MXS Technical Data, Rev. 3 46 Freescale Semiconductor Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[4] htrans Nonseq hwrite Read Write haddr V1 V8 Idle Nonseq hready hwdata weim_hrdata Last Valid Data Write Data Last Valid Data Read Data weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V8 CNC CS4 R/W Read Write LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) DATA DATA Read Data Last Valid Data Write Data Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 27. WSC = 2, OEA = 2, WEA = 1, WEN = 2, CNC = 3, A.HALF/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 47 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq Nonse hwrite Read Read haddr V1 V5 Idle hready weim_hrdata weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 Address V5 CS2 Read R/W LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) ECB DATA V1 Word V2 Word V5 Word V6 Word Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 28. WSC = 3, SYNC = 1, A.HALF/E.HALF MC9328MXS Technical Data, Rev. 3 48 Freescale Semiconductor Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq Seq Seq Seq hwrite Read Read Read Read haddr V1 V2 V3 V4 Idle hready weim_hrdata Last Valid Data V1 Word V2 Word V3 Word V4 Word weim_hready BCLK (burst clock) ADDR Last Valid Addr Address V1 CS2 Read R/W LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) ECB DATA V1 Word V2 Word V3 Word V4 Word Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 29. WSC = 2, SYNC = 1, DOL = [1/0], A.WORD/E.WORD MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 49 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Nonseq Seq hwrite Read Read haddr V1 V2 Idle hready weim_hrdata Last Valid Data V1 Word V2 Word weim_hready BCLK (burst clock) ADDR Last Valid Address V1 Address V2 CS2 Read R/W LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) ECB DATA V1 1/2 V1 2/2 V2 1/2 V2 2/2 Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 30. WSC = 2, SYNC = 1, DOL = [1/0], A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 50 Freescale Semiconductor Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Non seq Seq hwrite Read Read haddr V1 V2 Idle hready weim_hrdata Last Valid Data V1 Word V2 Word weim_hready BCLK (burst clock) ADDR Last Address V1 CS2 R/W Read LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) ECB DATA V1 1/2 V1 2/2 V2 1/2 V2 2/2 Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 31. WSC = 7, OEA = 8, SYNC = 1, DOL = 1, BCD = 1, BCS = 2, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 51 Functional Description and Application Information Internal signals - shown only for illustrative purposes hclk hsel_weim_cs[2] htrans Non seq Seq hwrite Read Read haddr V1 V2 Idle hready weim_hrdata Last Valid Data V1 Word V2 Word weim_hready BCLK (burst clock) ADDR Last Address V1 CS2 R/W Read LBA OE EBx1 (EBC2=0) EBx1 (EBC2=1) ECB DATA V1 1/2 V1 2/2 V2 1/2 V2 2/2 Note 1: x = 0, 1, 2 or 3 Note 2: EBC = Enable Byte Control bit (bit 11) on the Chip Select Control Register Figure 32. WSC = 7, OEA = 8, SYNC = 1, DOL = 1, BCD = 1, BCS = 1, A.WORD/E.HALF MC9328MXS Technical Data, Rev. 3 52 Freescale Semiconductor Functional Description and Application Information 4.4.4 Non-TFT Panel Timing T1 T1 VSYN T3 T2 T4 XMAX T2 HSYN SCLK Ts LD[15:0] Figure 33. Non-TFT Panel Timing Table 17. Non TFT Panel Timing Diagram Symbol Parameter Allowed Register Minimum Value1, 2 Actual Value Unit T1 HSYN to VSYN delay3 0 HWAIT2+2 Tpix4 T2 HSYN pulse width 0 HWIDTH+1 Tpix T3 VSYN to SCLK – 0 ≤ T3 ≤ Ts5 – T4 SCLK to HSYN 0 HWAIT1+1 Tpix 1 Maximum frequency of LCDC_CLK is 48 MHz, which is controlled by Peripheral Clock Divider Register. Maximum frequency of SCLK is HCLK / 5, otherwise LD output will be wrong. 3 VSYN, HSYN and SCLK can be programmed as active high or active low. In the above timing diagram, all these 3 signals are active high. 4 Tpix is the pixel clock period which equals LCDC_CLK period * (PCD + 1). 5 Ts is the shift clock period. Ts = Tpix * (panel data bus width). 2 4.5 SPI Timing Diagrams To use the internal transmit (TX) and receive (RX) data FIFOs when the SPI module is configured as a master, two control signals are used for data transfer rate control: the SS signal (output) and the SPI_RDY signal (input). The SPI1 Sample Period Control Register (PERIODREG1) can also be programmed to a fixed data transfer rate. When the SPI module is configured as a slave, the user can configure the SPI1 Control Register (CONTROLREG1) to match the external SPI master’s timing. In this configuration, SS becomes an input signal, and is used to latch data into or load data out to the internal data shift registers, as well as to increment the data FIFO. Figure 34 through Figure 38 show the timing relationship of the master SPI using different triggering mechanisms. MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 53 Functional Description and Application Information 2 SS 5 3 1 4 SPIRDY SCLK, MOSI, MISO Figure 34. Master SPI Timing Diagram Using SPI_RDY Edge Trigger SS SPIRDY SCLK, MOSI, MISO Figure 35. Master SPI Timing Diagram Using SPI_RDY Level Trigger SS (output) SCLK, MOSI, MISO Figure 36. Master SPI Timing Diagram Ignore SPI_RDY Level Trigger SS (input) SCLK, MOSI, MISO Figure 37. Slave SPI Timing Diagram FIFO Advanced by BIT COUNT SS (input) 6 7 SCLK, MOSI, MISO Figure 38. Slave SPI Timing Diagram FIFO Advanced by SS Rising Edge MC9328MXS Technical Data, Rev. 3 54 Freescale Semiconductor Functional Description and Application Information Table 18. Timing Parameter Table for Figure 34 through Figure 38 3.0 ± 0.3 V Ref No. Parameter Unit Minimum Maximum 2T1 – ns 1 SPI_RDY to SS output low 2 SS output low to first SCLK edge 3 • Tsclk2 – ns 3 Last SCLK edge to SS output high 2 • Tsclk – ns 4 SS output high to SPI_RDY low 0 – ns 5 SS output pulse width Tsclk + WAIT 3 – ns 6 SS input low to first SCLK edge T – ns 7 SS input pulse width T – ns 1 T = CSPI system clock period (PERCLK2). Tsclk = Period of SCLK. 3 WAIT = Number of bit clocks (SCLK) or 32.768 kHz clocks per Sample Period Control Register. 2 8 SCLK 9 9 Figure 39. SPI SCLK Timing Diagram Table 19. Timing Parameter Table for SPI SCLK 3.0 ± 0.3 V Ref No. 4.6 Parameter 8 SCLK frequency 9 SCLK pulse width Unit Minimum Maximum 0 10 MHz 100 – ns LCD Controller This section includes timing diagrams for the LCD controller. For detailed timing diagrams of the LCD controller with various display configurations, refer to the LCD controller chapter of the MC9328MXS Reference Manual. LSCLK 1 LD[15:0] Figure 40. SCLK to LD Timing Diagram MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 55 Functional Description and Application Information Table 20. LCDC SCLK Timing Parameter Table 3.0 ± 0.3 V Ref No. 1 Parameter Minimum Maximum Unit – 2 ns SCLK to LD valid Non-display VSYN Display region T3 T1 T4 T2 HSYN OE LD[15:0] Line Y Line 1 T5 T6 Line Y T7 XMAX HSYN SCLK OE T8 LD[15:0] (1,1) (1,2) (1,X) VSYN T9 T10 Figure 41. 4/8/16 Bit/Pixel TFT Color Mode Panel Timing Table 21. 4/8/16 Bit/Pixel TFT Color Mode Panel Timing Symbol Description Minimum Corresponding Register Value Unit T1 End of OE to beginning of VSYN T5+T6 +T7+T9 (VWAIT1·T2)+T5+T6+T7+T9 Ts T2 HSYN period XMAX+5 XMAX+T5+T6+T7+T9+T10 Ts T3 VSYN pulse width T2 VWIDTH·(T2) Ts T4 End of VSYN to beginning of OE 2 VWAIT2·(T2) Ts T5 HSYN pulse width 1 HWIDTH+1 Ts T6 End of HSYN to beginning to T9 1 HWAIT2+1 Ts T7 End of OE to beginning of HSYN 1 HWAIT1+1 Ts MC9328MXS Technical Data, Rev. 3 56 Freescale Semiconductor Functional Description and Application Information Table 21. 4/8/16 Bit/Pixel TFT Color Mode Panel Timing (Continued) Symbol Description Minimum Corresponding Register Value Unit T8 SCLK to valid LD data -3 3 ns T9 End of HSYN idle2 to VSYN edge (for non-display region) 2 2 Ts T9 End of HSYN idle2 to VSYN edge (for Display region) 1 1 Ts T10 VSYN to OE active (Sharp = 0) when VWAIT2 = 0 1 1 Ts T10 VSYN to OE active (Sharp = 1) when VWAIT2 = 0 2 2 Ts Note: • • • • • • 4.7 Ts is the SCLK period which equals LCDC_CLK / (PCD + 1). Normally LCDC_CLK = 15ns. VSYN, HSYN and OE can be programmed as active high or active low. In Figure 41, all 3 signals are active low. The polarity of SCLK and LD[15:0] can also be programmed. SCLK can be programmed to be deactivated during the VSYN pulse or the OE deasserted period. In Figure 41, SCLK is always active. For T9 non-display region, VSYN is non-active. It is used as an reference. XMAX is defined in pixels. Pulse-Width Modulator The PWM can be programmed to select one of two clock signals as its source frequency. The selected clock signal is passed through a divider and a prescaler before being input to the counter. The output is available at the pulse-width modulator output (PWMO) external pin. Its timing diagram is shown in Figure 42 and the parameters are listed in Table 22. 1 2a 3b System Clock 2b 3a 4b 4a PWM Output Figure 42. PWM Output Timing Diagram MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 57 Functional Description and Application Information Table 22. PWM Output Timing Parameter Table 1.8 ± 0.1 V Ref No. 1 4.8 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum 0 87 0 100 MHz 1 System CLK frequency1 2a Clock high time1 3.3 – 5/10 – ns 2b Clock low time1 7.5 – 5/10 – ns 3a Clock fall time1 – 5 – 5/10 ns 3b Clock rise time1 – 6.67 – 5/10 ns 4a Output delay time1 5.7 – 5 – ns 4b Output setup time1 5.7 – 5 – ns CL of PWMO = 30 pF SDRAM Controller This section shows timing diagrams and parameters associated with the SDRAM (synchronous dynamic random access memory) Controller. MC9328MXS Technical Data, Rev. 3 58 Freescale Semiconductor Functional Description and Application Information 1 SDCLK 2 3S 3 CS 3H 3S RAS 3S 3H CAS 3S 3H 3H WE 4S ADDR 4H ROW/BA COL/BA 5 8 6 DQ Data 7 3S DQM 3H Note: CKE is high during the read/write cycle. Figure 43. SDRAM Read Cycle Timing Diagram Table 23. SDRAM Read Timing Parameter Table 1.8 ± 0.1 V Ref No. 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum 1 SDRAM clock high-level width 2.67 – 4 – ns 2 SDRAM clock low-level width 6 – 4 – ns 3 SDRAM clock cycle time 11.4 – 10 – ns 3S CS, RAS, CAS, WE, DQM setup time 3.42 – 3 – ns 3H CS, RAS, CAS, WE, DQM hold time 2.28 – 2 – ns 4S Address setup time 3.42 – 3 – ns 4H Address hold time 2.28 – 2 – ns – 6.84 – 6 ns 5 SDRAM access time (CL = 3) MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 59 Functional Description and Application Information Table 23. SDRAM Read Timing Parameter Table (Continued) 1.8 ± 0.1 V Ref No. 1 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum 5 SDRAM access time (CL = 2) – 6.84 – 6 ns 5 SDRAM access time (CL = 1) – 22 – 22 ns 6 Data out hold time 2.85 – 2.5 – ns 7 Data out high-impedance time (CL = 3) – 6.84 – 6 ns 7 Data out high-impedance time (CL = 2) – 6.84 – 6 ns 7 Data out high-impedance time (CL = 1) – 22 – 22 ns 8 Active to read/write command period (RC = 1) tRCD1 – tRCD1 – ns tRCD = SDRAM clock cycle time. This settings can be found in the MC9328MXS reference manual. SDCLK 1 2 3 CS RAS 6 CAS WE 5 7 4 ADDR / BA COL/BA ROW/BA 8 9 DATA DQ DQM Figure 44. SDRAM Write Cycle Timing Diagram MC9328MXS Technical Data, Rev. 3 60 Freescale Semiconductor Functional Description and Application Information Table 24. SDRAM Write Timing Parameter Table 1.8 ± 0.1 V Ref No. 1 2 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum 1 SDRAM clock high-level width 2.67 – 4 – ns 2 SDRAM clock low-level width 6 – 4 – ns 3 SDRAM clock cycle time 11.4 – 10 – ns 4 Address setup time 3.42 – 3 – ns 5 Address hold time 2.28 – 2 – ns tRP2 – tRP2 – ns tRCD2 – tRCD2 – ns period1 6 Precharge cycle 7 Active to read/write command delay 8 Data setup time 4.0 – 2 – ns 9 Data hold time 2.28 – 2 – ns Precharge cycle timing is included in the write timing diagram. tRP and tRCD = SDRAM clock cycle time. These settings can be found in the MC9328MXS reference manual. SDCLK 1 3 2 CS RAS 6 CAS 7 7 WE 4 ADDR 5 ROW/BA BA DQ DQM Figure 45. SDRAM Refresh Timing Diagram MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 61 Functional Description and Application Information Table 25. SDRAM Refresh Timing Parameter Table 1.8 ± 0.1 V Ref No. 1 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum 1 SDRAM clock high-level width 2.67 – 4 – ns 2 SDRAM clock low-level width 6 – 4 – ns 3 SDRAM clock cycle time 11.4 – 10 – ns 4 Address setup time 3.42 – 3 – ns 5 Address hold time 2.28 – 2 – ns 6 Precharge cycle period tRP1 – tRP1 – ns 7 Auto precharge command period tRC1 – tRC1 – ns tRP and tRC = SDRAM clock cycle time. These settings can be found in the MC9328MXS reference manual. SDCLK CS RAS CAS WE ADDR BA DQ DQM CKE Figure 46. SDRAM Self-Refresh Cycle Timing Diagram MC9328MXS Technical Data, Rev. 3 62 Freescale Semiconductor Functional Description and Application Information 4.9 USB Device Port Four types of data transfer modes exist for the USB module: control transfers, bulk transfers, isochronous transfers, and interrupt transfers. From the perspective of the USB module, the interrupt transfer type is identical to the bulk data transfer mode, and no additional hardware is supplied to support it. This section covers the transfer modes and how they work from the ground up. Data moves across the USB in packets. Groups of packets are combined to form data transfers. The same packet transfer mechanism applies to bulk, interrupt, and control transfers. Isochronous data is also moved in the form of packets, however, because isochronous pipes are given a fixed portion of the USB bandwidth at all times, there is no end-of-transfer. USBD_AFE (Output) 1 t VMO_ROE 4 t ROE_VPO USBD_ROE (Output) tPERIOD 6 3 tVPO_ROE USBD_VPO (Output) USBD_VMO (Output) USBD_SUSPND tROE_VMO 2 tFEOPT 5 (Output) USBD_RCV (Input) USBD_VP (Input) USBD_VM (Input) Figure 47. USB Device Timing Diagram for Data Transfer to USB Transceiver (TX) Table 26. USB Device Timing Parameters for Data Transfer to USB Transceiver (TX) 3.0 ± 0.3 V Ref No. Parameter Unit Minimum Maximum 1 tROE_VPO; USBD_ROE active to USBD_VPO low 83.14 83.47 ns 2 tROE_VMO; USBD_ROE active to USBD_VMO high 81.55 81.98 ns 3 tVPO_ROE; USBD_VPO high to USBD_ROE deactivated 83.54 83.80 ns 4 tVMO_ROE; USBD_VMO low to USBD_ROE deactivated (includes SE0) 248.90 249.13 ns MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 63 Functional Description and Application Information Table 26. USB Device Timing Parameters for Data Transfer to USB Transceiver (TX) (Continued) 3.0 ± 0.3 V Ref No. Parameter Unit Minimum Maximum 5 tFEOPT; SE0 interval of EOP 160.00 175.00 ns 6 tPERIOD; Data transfer rate 11.97 12.03 Mb/s USBD_AFE (Output) USBD_ROE (Output) USBD_VPO (Output) USBD_VMO (Output) USBD_SUSPND (Output) USBD_RCV (Input) 1 tFEOPR USBD_VP (Input) USBD_VM (Input) Figure 48. USB Device Timing Diagram for Data Transfer from USB Transceiver (RX) Table 27. USB Device Timing Parameter Table for Data Transfer from USB Transceiver (RX) 3.0 ± 0.3 V Ref No. 1 4.10 Parameter tFEOPR; Receiver SE0 interval of EOP Unit Minimum Maximum 82 – ns I2C Module The I2C communication protocol consists of seven elements: START, Data Source/Recipient, Data Direction, Slave Acknowledge, Data, Data Acknowledge, and STOP. MC9328MXS Technical Data, Rev. 3 64 Freescale Semiconductor Functional Description and Application Information SDA 5 3 4 SCL 2 1 6 Figure 49. Definition of Bus Timing for I2C Table 28. I2C Bus Timing Parameter Table 1.8 ± 0.1 V Ref No. 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum 182 – 160 – ns 1 Hold time (repeated) START condition 2 Data hold time 0 171 0 150 ns 3 Data setup time 11.4 – 10 – ns 4 HIGH period of the SCL clock 80 – 120 – ns 5 LOW period of the SCL clock 480 – 320 – ns 6 Setup time for STOP condition 182.4 – 160 – ns 4.11 Synchronous Serial Interface The transmit and receive sections of the SSI can be synchronous or asynchronous. In synchronous mode, the transmitter and the receiver use a common clock and frame synchronization signal. In asynchronous mode, the transmitter and receiver each have their own clock and frame synchronization signals. Continuous or gated clock mode can be selected. In continuous mode, the clock runs continuously. In gated clock mode, the clock functions only during transmission. The internal and external clock timing diagrams are shown in Figure 51 through Figure 53. Normal or network mode can also be selected. In normal mode, the SSI functions with one data word of I/O per frame. In network mode, a frame can contain between 2 and 32 data words. Network mode is typically used in star or ring-time division multiplex networks with other processors or codecs, allowing interface to time division multiplexed networks without additional logic. Use of the gated clock is not allowed in network mode. These distinctions result in the basic operating modes that allow the SSI to communicate with a wide variety of devices. MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 65 Functional Description and Application Information 1 STCK Output 4 2 STFS (bl) Output 6 8 STFS (wl) Output 12 10 11 STXD Output 31 32 SRXD Input Note: SRXD input in synchronous mode only. Figure 50. SSI Transmitter Internal Clock Timing Diagram 1 SRCK Output 3 5 SRFS (bl) Output 7 9 SRFS (wl) Output 13 14 SRXD Input Figure 51. SSI Receiver Internal Clock Timing Diagram MC9328MXS Technical Data, Rev. 3 66 Freescale Semiconductor Functional Description and Application Information 15 16 17 STCK Input 18 20 STFS (bl) Input 24 22 STFS (wl) Input 27 26 28 STXD Output 34 33 SRXD Input Note: SRXD Input in Synchronous mode only Figure 52. SSI Transmitter External Clock Timing Diagram 15 16 17 SRCK Input 19 21 SRFS (bl) Input 25 23 SRFS (wl) Input 30 29 SRXD Input Figure 53. SSI Receiver External Clock Timing Diagram Table 29. SSI (Port C Primary Function) Timing Parameter Table 1.8 ± 0.1 V Ref No. 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum Internal Clock Operation1 (Port C Primary Function2) STCK/SRCK clock period1 95 – 83.3 – ns 2 3 STCK high to STFS (bl) high 1.5 4.5 1.3 3.9 ns 3 SRCK high to SRFS (bl) high3 1 -1.2 -1.7 -1.1 -1.5 ns 4 3 STCK high to STFS (bl) low 2.5 4.3 2.2 3.8 ns 5 SRCK high to SRFS (bl) low3 0.1 -0.8 0.1 -0.8 ns MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 67 Functional Description and Application Information Table 29. SSI (Port C Primary Function) Timing Parameter Table (Continued) 1.8 ± 0.1 V Ref No. 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum 6 STCK high to STFS (wl) high3 1.48 4.45 1.3 3.9 ns 7 3 SRCK high to SRFS (wl) high -1.1 -1.5 -1.1 -1.5 ns 8 STCK high to STFS (wl) low3 2.51 4.33 2.2 3.8 ns 9 3 SRCK high to SRFS (wl) low 0.1 -0.8 0.1 -0.8 ns 10 STCK high to STXD valid from high impedance 14.25 15.73 12.5 13.8 ns 11a STCK high to STXD high 0.91 3.08 0.8 2.7 ns 11b STCK high to STXD low 0.57 3.19 0.5 2.8 ns 12 STCK high to STXD high impedance 12.88 13.57 11.3 11.9 ns 13 SRXD setup time before SRCK low 21.1 – 18.5 – ns 14 SRXD hold time after SRCK low 0 – 0 – ns External Clock Operation (Port C Primary Function2) 15 STCK/SRCK clock period1 92.8 – 81.4 – ns 16 STCK/SRCK clock high period 27.1 – 40.7 – ns 17 STCK/SRCK clock low period 61.1 – 40.7 – ns 18 STCK high to STFS (bl) high3 – 92.8 0 81.4 ns 19 SRCK high to SRFS (bl) high3 – 92.8 0 81.4 ns 20 STCK high to STFS (bl) low3 – 92.8 0 81.4 ns 21 SRCK high to SRFS (bl) low3 – 92.8 0 81.4 ns 22 STCK high to STFS (wl) high3 – 92.8 0 81.4 ns 23 SRCK high to SRFS (wl) high3 – 92.8 0 81.4 ns 24 STCK high to STFS (wl) low3 – 92.8 0 81.4 ns 25 SRCK high to SRFS (wl) low3 – 92.8 0 81.4 ns 26 STCK high to STXD valid from high impedance 18.01 28.16 15.8 24.7 ns 27a STCK high to STXD high 8.98 18.13 7.0 15.9 ns 27b STCK high to STXD low 9.12 18.24 8.0 16.0 ns 28 STCK high to STXD high impedance 18.47 28.5 16.2 25.0 ns 29 SRXD setup time before SRCK low 1.14 – 1.0 – ns 30 SRXD hole time after SRCK low 0 – 0 – ns Synchronous Internal Clock Operation (Port C Primary Function2) 31 SRXD setup before STCK falling 32 SRXD hold after STCK falling 15.4 – 13.5 – ns 0 – 0 – ns MC9328MXS Technical Data, Rev. 3 68 Freescale Semiconductor Functional Description and Application Information Table 29. SSI (Port C Primary Function) Timing Parameter Table (Continued) 1.8 ± 0.1 V Ref No. 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum Synchronous External Clock Operation (Port C Primary Function2) 33 SRXD setup before STCK falling 34 SRXD hold after STCK falling 1.14 – 1.0 – ns 0 – 0 – ns 1 All the timings for the SSI are given for a non-inverted serial clock polarity (TSCKP/RSCKP = 0) and a non-inverted frame sync (TFSI/RFSI = 0). If the polarity of the clock and/or the frame sync have been inverted, all the timing remains valid by inverting the clock signal STCK/SRCK and/or the frame sync STFS/SRFS shown in the tables and in the figures. 2 There are 2 sets of I/O signals for the SSI module. They are from Port C primary function (pad 257 to pad 261) and Port B alternate function (pad 283 to pad 288). When SSI signals are configured as outputs, they can be viewed both at Port C primary function and Port B alternate function. When SSI signals are configured as input, the SSI module selects the input based on status of the FMCR register bits in the Clock controller module (CRM). By default, the input are selected from Port C primary function. 3 bl = bit length; wl = word length. Table 30. SSI (Port B Alternate Function) Timing Parameter Table 1.8 ± 0.1 V Ref No. 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum Internal Clock Operation1 (Port B Alternate Function2) 1 STCK/SRCK clock period1 95 – 83.3 – ns 2 STCK high to STFS (bl) high3 1.7 4.8 1.5 4.2 ns 3 SRCK high to SRFS (bl) high3 -0.1 1.0 -0.1 1.0 ns 4 STCK high to STFS (bl) low3 3.08 5.24 2.7 4.6 ns 5 SRCK high to SRFS (bl) low3 1.25 2.28 1.1 2.0 ns 6 STCK high to STFS (wl) high3 1.71 4.79 1.5 4.2 ns 7 SRCK high to SRFS (wl) high3 -0.1 1.0 -0.1 1.0 ns 8 STCK high to STFS (wl) low3 3.08 5.24 2.7 4.6 ns 9 3 SRCK high to SRFS (wl) low 1.25 2.28 1.1 2.0 ns 10 STCK high to STXD valid from high impedance 14.93 16.19 13.1 14.2 ns 11a STCK high to STXD high 1.25 3.42 1.1 3.0 ns 11b STCK high to STXD low 2.51 3.99 2.2 3.5 ns 12 STCK high to STXD high impedance 12.43 14.59 10.9 12.8 ns 13 SRXD setup time before SRCK low 20 – 17.5 – ns 14 SRXD hold time after SRCK low 0 – 0 – ns MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 69 Functional Description and Application Information Table 30. SSI (Port B Alternate Function) Timing Parameter Table (Continued) Ref No. 1.8 ± 0.1 V 3.0 ± 0.3 V Parameter Unit Minimum Maximum Minimum Maximum External Clock Operation (Port B Alternate Function2) 15 STCK/SRCK clock period1 92.8 – 81.4 – ns 16 STCK/SRCK clock high period 27.1 – 40.7 – ns 17 STCK/SRCK clock low period 61.1 – 40.7 – ns 18 STCK high to STFS (bl) high3 – 92.8 0 81.4 ns 19 3 SRCK high to SRFS (bl) high – 92.8 0 81.4 ns 20 STCK high to STFS (bl) low3 – 92.8 0 81.4 ns 21 SRCK high to SRFS (bl) low3 – 92.8 0 81.4 ns 22 STCK high to STFS (wl) high3 – 92.8 0 81.4 ns 23 SRCK high to SRFS (wl) high3 – 92.8 0 81.4 ns 24 STCK high to STFS (wl) low3 – 92.8 0 81.4 ns 25 SRCK high to SRFS (wl) low3 – 92.8 0 81.4 ns 26 STCK high to STXD valid from high impedance 18.9 29.07 16.6 25.5 ns 27a STCK high to STXD high 9.23 20.75 8.1 18.2 ns 27b STCK high to STXD low 10.60 21.32 9.3 18.7 ns 28 STCK high to STXD high impedance 17.90 29.75 15.7 26.1 ns 29 SRXD setup time before SRCK low 1.14 – 1.0 – ns 30 SRXD hold time after SRCK low 0 – 0 – ns Synchronous Internal Clock Operation (Port B Alternate Function2) 31 SRXD setup before STCK falling 32 SRXD hold after STCK falling 18.81 – 16.5 – ns 0 – 0 – ns Synchronous External Clock Operation (Port B Alternate Function2) 33 SRXD setup before STCK falling 34 SRXD hold after STCK falling 1.14 – 1.0 – ns 0 – 0 – ns 1 All the timings for the SSI are given for a non-inverted serial clock polarity (TSCKP/RSCKP = 0) and a non-inverted frame sync (TFSI/RFSI = 0). If the polarity of the clock and/or the frame sync have been inverted, all the timing remains valid by inverting the clock signal STCK/SRCK and/or the frame sync STFS/SRFS shown in the tables and in the figures. 2 There are 2 set of I/O signals for the SSI module. They are from Port C primary function (pad 257 to pad 261) and Port B alternate function (pad 283 to pad 288). When SSI signals are configured as outputs, they can be viewed both at Port C primary function and Port B alternate function. When SSI signals are configured as inputs, the SSI module selects the input based on FMCR register bits in the Clock controller module (CRM). By default, the input are selected from Port C primary function. 3 bl = bit length; wl = word length. MC9328MXS Technical Data, Rev. 3 70 Freescale Semiconductor reescale Semiconductor 5 Pin-Out and Package Information Table 31 illustrates the package pin assignments for the 225-contact MAPBGA package. For a complete listing of signals, see the Signal Multiplexing Table 3 on page 8. Table 31. i.MXS 225 MAPBGA Pin Assignments MC9328MXS Technical Data, Rev. 3 2 2 3 4 5 6 7 8 9 10 11 12 13 14 15 A PB13 PB15 PB19 USBD_ ROE USBD_ SUSPND USBD_VM SSI_ RXFS SSI_ TXCLK SPI1_SPI_ RDY SPI1_ SCLK REV PS LD2 LD4 LD5 A B PB11 PB12 PB16 USBD_ AFE USBD_ RCV USBD_ VMO SSI_ RXDAT UART1_ TXD SPI1_SS LSCLK SPL_ SPR LD0 LD3 LD6 LD7 B C D31 PB8 PB14 PB18 PB10 USBD_ VPO UART2_ RXD SSI_ TXFS UART1_ RTS LD8 LD9 LD12 NVDD2 C D A23 A24 PB9 PB17 NVDD1 USBD_ VP QVDD4 UART2_ TXD NVDD3 SPI1_ MOSI LP/HSYNC LD1 LD11 TMR2OUT LD13 D E A21 A22 D30 D29 NVDD1 QVSS UART2_ RTS UART1_ RXD UART1_ CTS SPI1_ MISO ACD/OE LD10 TIN PA4 PA3 E F A20 A19 D28 D27 NVDD1 NVDD1 UART2_ CTS SSI_ RXCLK SSI_ TXDAT CLS QVDD3 LD14 LD15 PA6 PA8 F G A17 A18 D26 D25 NVDD1 NVSS NVDD4 NVSS NVSS QVSS PWMO PA7 PA11 PA13 PA9 G H A15 A16 D23 D24 D22 NVSS NVSS NVSS NVSS NVDD2 PA5 PA12 PA14 I2C_SDA TMS H J A14 A12 D21 D20 NVDD1 NVSS NVSS QVDD1 NVSS PA10 I2C_SCL TCK TDO BOOT1 BOOT0 J K A13 A11 CS2 D19 NVDD1 NVSS QVSS NVDD1 NVSS D1 BOOT2 TDI BIG_ ENDIAN RESET_ OUT XTAL32K K L A10 A9 D17 D18 NVDD1 NVDD1 CS5 D2 ECB NVSS NVSS POR QVSS XTAL16M EXTAL32K L M D16 D15 D13 D10 EB3 NVDD1 CS4 CS1 BCLK1 RW NVSS BOOT3 QVDD2 RESET_IN EXTAL16M M N A8 A7 D12 EB0 D9 D8 CS3 CS0 PA17 D0 DQM2 DQM0 SDCKE0 TRISTATE TRST N P D14 A5 A4 A3 A2 A1 D6 D5 MA10 MA11 DQM1 RAS SDCKE1 CLKO RESET_SF2 P R A6 D11 EB1 EB2 OE D7 A0 SDCLK D4 LBA D3 DQM3 CAS SDWE AVDD1 R 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Burst Clock This signal is not used and should be floated in an actual application. CONTRAST FLM/VSYNC 71 Pin-Out and Package Information 1 1 Pin-Out and Package Information 5.1 MAPBGA 225 Package Dimensions Figure 54 illustrates the 225 MAPBGA 13 mm × 13 mm package. Case Outline 1304B TOP VIEW BOTTOM VIEW SIDE VIEW NOTES: 1. ALL DIMENSIONS ARE IN MILLIMETERS. 2.DIMENSIONS AND TOLERANCES PER ASME Y14 5M-1994. 3.MAXIMUM SOLDER BALL DIAMETER MEASURED PARALLEL TO DATUM A. 4. DATUM A, THE SEATING PLANE IS DEFINED BY SPHERICAL CROWNS OF THE SOLDER BALLS. 5.PARALLELISM MEASUREMENT SHALL EXCLUDE ANY EFFECT OF MARK ON TOP SURFACE OF PACKAGE Figure 54. i.MXS 225 MAPBGA Mechanical Drawing MC9328MXS Technical Data, Rev. 3 72 Freescale Semiconductor Product Documentation 6 6.1 Product Documentation Revision History Table 32 provides revision history for this release. This history includes technical content revisions only and not stylistic or grammatical changes. Table 32. i.MXS Data Sheet Revision History Rev. 3 Location Revision Table 2 on page 4 Signal Names and Descriptions • Added the DMA_REQ signal to table. • Corrected signal name from USBD_OE to USBD_ROE Table 3 on page 8 Signal Multiplex Table i.MXS Added Signal Multiplex table from Reference Manual with the following changes: • Corrected BGA pin assignments. Table 10 on page 20 Changed first and second parameters descriptions: From: Reference Clock freq range, To: DPLL input clock freq range From: Double clock freq range, To: DPLL output freq range 6.2 Reference Documents The following documents are required for a complete description of the MC9328MXS and are necessary to design properly with the device. Especially for those not familiar with the ARM920T processor or previous i.MX processor products, the following documents are helpful when used in conjunction with this document. ARM Architecture Reference Manual (ARM Ltd., order number ARM DDI 0100) ARM9DT1 Data Sheet Manual (ARM Ltd., order number ARM DDI 0029) ARM Technical Reference Manual (ARM Ltd., order number ARM DDI 0151C) EMT9 Technical Reference Manual (ARM Ltd., order number DDI O157E) MC9328MXS Product Brief (order number MC9328MXSP) MC9328MXS Reference Manual (order number MC9328MXSRM) The Freescale manuals are available on the Freescale Semiconductors Web site at http://www.freescale.com/imx. These documents may be downloaded directly from the Freescale Web site, or printed versions may be ordered. The ARM Ltd. documentation is available from http://www.arm.com. MC9328MXS Technical Data, Rev. 3 Freescale Semiconductor 73 How to Reach Us: Home Page: www.freescale.com E-mail: [email protected] USA/Europe or Locations Not Listed: Freescale Semiconductor Technical Information Center, CH370 1300 N. Alma School Road Chandler, Arizona 85224 +1-800-521-6274 or +1-480-768-2130 [email protected] 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) [email protected] 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 [email protected] Asia/Pacific: Freescale Semiconductor Hong Kong Ltd. Technical Information Center 2 Dai King Street Tai Po Industrial Estate Tai Po, N.T., Hong Kong +800 2666 8080 [email protected] For Literature Requests Only: Freescale Semiconductor Literature Distribution Center P.O. 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