ISP1160BM01FE ST-Ericsson Inc, ISP1160BM01FE Datasheet

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IMPORTANT NOTICE Dear customer from August 2 2008, the wireless operations of NXP have moved to a new company, ST-NXP Wireless result, the following changes are applicable to the attached document. ● Company name - Philips ...

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General description The ISP1160 is an embedded Universal Serial Bus (USB) Host Controller (HC) that complies with Universal Serial Bus Specification Rev. 2.0 , supporting data transfer at full-speed (12 Mbit/s) and low-speed (1.5 Mbit/s). The ISP1160 provides two ...

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Philips Semiconductors 3. Applications 4. Ordering information Table 1: Type number ISP1160BD ISP1160BD/01 ISP1160BM ISP1160BM/01 [1] [2] 9397 750 13963 Product data Personal Digital Assistant (PDA) Digital camera Third-generation (3-G) phone Set-Top Box (STB) Information Appliance (IA) Photo printer MP3 ...

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H_WAKEUP 42 H_SUSPEND 33 NDP_SEL 14, 16, 17, 16 63, 64 ISP1160 D0 to D15 22 RD_N 21 CS_N 23 MICROPROCESSOR WR_N 59 BUS INTERFACE A0 27 DACK_N 34 EOT 25 DREQ 29 INT ...

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Philips Semiconductors 6. Pinning information 6.1 Pinning DGND DGND DGND Fig 2. Pin configuration LQFP64. 6.2 Pin description Table 2: Symbol DGND D2 D3 9397 750 13963 Product data ...

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Philips Semiconductors Table 2: Symbol DGND D8 D9 D10 D11 D12 D13 DGND D14 D15 DGND V HOLD1 n.c. CS_N RD_N WR_N V HOLD2 DREQ 9397 750 13963 Product data Pin description LQFP64 …continued [1] Pin ...

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Philips Semiconductors Table 2: Symbol n.c. DACK_N TEST_HIGH INT n.c. n.c. RESET_N NDP_SEL EOT DGND n.c. TEST_LOW n.c. TEST_LOW H_WAKEUP n.c. H_SUSPEND XTAL1 XTAL2 DGND H_PSW1_N 9397 750 13963 Product data Pin description LQFP64 …continued [1] Pin Type Description 26 ...

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Philips Semiconductors Table 2: Symbol H_PSW2_N n.c. n.c. H_DM1 H_DP1 H_DM2 H_DP2 H_OC1_N H_OC2_N V CC AGND V REG(3V3) A0 LOW_PW n.c. DGND D0 D1 [1] 9397 750 13963 Product data Pin description LQFP64 [1] Pin Type Description 47 O ...

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Philips Semiconductors 7. Functional description 7.1 PLL clock multiplier A 6 MHz to 48 MHz clock multiplier Phase-Locked Loop (PLL) is integrated on-chip. This allows for the use of a low-cost 6 MHz crystal, which also minimizes EMI. No external ...

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Philips Semiconductors Fig 3. Programmed I/O interface between a microprocessor and the ISP1160. 8.2 DMA mode The ISP1160 also provides the DMA mode for external microprocessors to access its internal FIFO buffer RAM. Data can be transferred by the DMA ...

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Philips Semiconductors 8.3 Control registers access by PIO mode 8.3.1 I/O port addressing Table 3 address should include the chip select signal CS_N and the address line A0. However, the direction of access of I/O ports is controlled by the ...

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Philips Semiconductors Fig 6. 16-bit register access cycle. Most of the ISP1160’s internal control registers are 16-bit wide. Some of the internal control registers, however, are 32-bit wide. internal control register is accessed. The complete cycle of accessing a 32-bit ...

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Philips Semiconductors write command (16 bits) Fig 9. Internal FIFO buffer RAM access cycle. Figure 9 write cycle, the microprocessor first writes the FIFO buffer RAM’s command code to the command port, and then writes the data words one by ...

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Philips Semiconductors Fig 10. DMA transfer in single-cycle mode. DREQ DACK_N RD_N or WR_N D [ 15:0 ] data #1 EOT N 1/2 byte count of transfer data, K Fig 11. DMA transfer in burst mode. In Figure 10 HIGH ...

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Philips Semiconductors Figure 12 through the HcHardware Configuration register (see used to disable or enable the signals. Fig 12. Interrupt pin operating modes. 8.6.2 Interrupt output pin (INT) To program the four configuration modes of the HC’s interrupt output signal ...

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Philips Semiconductors HcInterruptEnable register MIE RHSC FNO RHSC FNO HcInterruptStatus register Fig 13. HC interrupt logic. There are two groups of interrupts represented by group 1 and group pair ...

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Philips Semiconductors To re-enable the interrupt generation: 1. Set all bits in the Hc PInterrupt register. 2. Set the InterruptPinEnable bit to logic 1. Remark: The InterruptPinEnable bit in the HcHardwareConfiguration register latches the interrupt output. When this bit is ...

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Philips Semiconductors USBOperational write USBSuspend write Fig 14. The ISP1160 HC’s USB states. The USB states are reflected in the HostControllerFunctionalState field of the HcControl register (01H to read, 81H to write), which is located at bits 7 and 6 ...

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Philips Semiconductors Reset HC state = USBOperational Initialize HC Entry Fig 15. ISP1160 HC USB transaction loop. Description of 1. Reset 2. Initialize HC 3. Entry 4. Need USB traffic 9397 750 13963 Product data Exit no yes Need Prepare ...

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Philips Semiconductors 5. Prepare PTD data in P system RAM 6. Transfer PTD data into HC’s FIFO buffer RAM 7. HC interprets PTD data 8. HC performs USB transactions via USB bus interface 9. HC informs HCD of the USB ...

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Philips Semiconductors The PTD data structure is used by the HC to define a buffer of data that will be moved to or from an endpoint in the USB device. This data buffer is set up for the current frame ...

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Philips Semiconductors Table 5: Philips Transfer Descriptor (PTD): bit description Symbol Access ActualBytes[9:0] R/W CompletionCode[3:0] R/W Active R/W Toggle R/W MaxPacketSize[9:0] R EndpointNumber[3:0] R Last R Speed R TotalBytes[9:0] R 9397 750 13963 Product data Contains the number of bytes ...

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Philips Semiconductors Table 5: Philips Transfer Descriptor (PTD): bit description Symbol Access DirectionPID[1:0] R B5_5 R/W Format R FunctionAddress[6:0] R 9.4 HC’s internal FIFO buffer RAM structure 9.4.1 Partitions According to the Universal Serial Bus Specification Rev. 2.0 , there ...

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Philips Semiconductors • ATL buffer length This is insufficient use of the internal FIFO buffer RAM. • ATL buffer length This will use the internal FIFO buffer RAM for only ATL transfers. Fig 17. HC internal FIFO buffer RAM partitions. ...

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Philips Semiconductors The data transfer can be done via the PIO mode or the DMA mode. The data transfer rate can Mbyte/s. In the DMA operation, the single-cycle or multi-cycle burst modes are supported. Multi-cycle burst ...

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Philips Semiconductors Fig 19. PTD data with DWORD alignment in buffer RAM. 9.4.3 Operation and C program example Figure 20 PIO mode. The ISP1160 provides one register as the access port for each buffer RAM. For the ITL buffer RAM, ...

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Philips Semiconductors Host bus I/F A0 000H 001H 3FFH ITL0 buffer RAM (8-bit width) Fig 20. PIO access to internal FIFO buffer RAM. Following is an example program that shows how to write data into the ATL ...

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Philips Semiconductors However, if communication with a peripheral USB device is desired, the device should be connected to the downstream port and pass enumeration. //The example program for writing ATL buffer RAM #include <conio.h> #include <stdio.h> #include <dos.h> //Define register ...

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Philips Semiconductors //write 80 (0x50) bytes of data into ATL buffer RAM for (i 0;i<wCount;i { outport(HcDataPort,PTDData[i]); }; //Check EOT interrupt bit wData printf("\n HC Interrupt Status //Check Buffer status register wData printf("\n HC Buffer Status } // // Read ...

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Philips Semiconductors the end of the frame for full-speed and low-speed packets. By programming these fields, the effective USB bus usage can be changed. Furthermore, the size of the ITL buffers (HcITLBufferLength, 2AH to read, AAH to write) is programmed. ...

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Philips Semiconductors ITL0BufferDone and ITL0BufferFull bits will be cleared automatically. This also applies to the ITL1 buffer because ITL0 and ITL1 are Ping-Pong structured buffers. To recover from this state, a power-on reset or software reset will have to be ...

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Philips Semiconductors (frame N) Fig 23. HC time domain behavior: example 3. 9.5.2 Control transaction limitations The different phases of a Control transfer (SETUP, Data and Status) should never be put in the same ATL. 9.6 Microprocessor loading The maximum ...

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Philips Semiconductors Fig 24. Use pull-down resistors on downstream ports. 9.8 Overcurrent detection and power switching control A downstream port provides 5 V power supply to V hardware functions to monitor the downstream ports loading conditions and ...

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Philips Semiconductors 9.8.1 Using an internal OC detection circuit The internal OC detection circuit can be used only when power supply. The HCD must set AnalogOCEnable, bit 10 of the HcHardwareConfiguration register, to logic 1. An ...

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Philips Semiconductors 9.8.2 Using an external OC detection circuit When V internal OC detection circuit cannot be used. An external OC detection circuit must be used instead. Regardless of the V always be used. To use an external OC detection ...

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Philips Semiconductors XOSC_6MHz XOSC On On VOLTAGE REGULATOR Fig 28. ISP1160 suspend and resume clock scheme. In the suspended state, the device will consume considerably less power by turning off the internal 48 MHz clock, PLL and crystal, and setting ...

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Philips Semiconductors Wake-up by pin CS_N (software wake-up): external microprocessor issues a chip select signal through pin CS_N to the ISP1160. This method of access to the ISP1160 internal registers is a software wake-up. Wake-up by USB devices: root hub ...

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Philips Semiconductors Table 7: HC registers summary Address (Hex) Register Read Write 12 92 HcRhDescriptorA 13 93 HcRhDescriptorB 14 94 HcRhStatus 15 95 HcRhPortStatus[ HcRhPortStatus[ HcHardwareConfiguration 21 A1 HcDMAConfiguration 22 A2 HcTransferCounter PInterrupt ...

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Philips Semiconductors Bit 7 Symbol Reset 0 Access R Table 9: Bit 10.1.2 HcControl register (R/W: 01H/81H) The HcControl register defines the operating modes of the HC. RemoteWakeupEnable (RWE) is modified only by the ...

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Philips Semiconductors Table 11: Bit 10.1.3 HcCommandStatus register (R/W: 02H/82H) The HcCommandStatus register is used by the HC to receive commands issued by the HCD, and it also ...

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Philips Semiconductors Code (Hex): 82 — write Table 12: HcCommandStatus register: bit allocation Bit 31 Symbol Reset 0 Access R Bit 23 Symbol Reset 0 Access R Bit 15 Symbol Reset 0 Access R/W R/W Bit 7 Symbol Reset 0 ...

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Philips Semiconductors Code (Hex): 03 — read Code (Hex): 83 — write Table 14: HcInteruptStatus register: bit allocation Bit 31 Symbol Reset 0 Access R/W R/W Bit 23 Symbol Reset 0 Access R/W R/W Bit 15 Symbol Reset 0 Access ...

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Philips Semiconductors 10.1.5 HcInterruptEnable register (R/W: 04H/84H) Each enable bit in the HcInterruptEnable register corresponds to an associated interrupt bit in the HcInterruptStatus register. The HcInterruptEnable register is used to control which events generate a hardware interrupt. A hardware interrupt ...

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Philips Semiconductors Table 17: Bit 10.1.6 HcInterruptDisable register (R/W: 05H/85H) Each disable bit in the HcInterruptDisable register corresponds to an associated interrupt bit in the HcInterruptStatus register. The HcInterruptDisable ...

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Philips Semiconductors Bit 7 Symbol reserved RHSC Reset 0 Access R/W R/W Table 19: Bit 10.2 HC frame counter registers 10.2.1 HcFmInterval register (R/W: 0DH/8DH) The HcFmInterval register contains ...

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Philips Semiconductors Bit 23 Symbol Reset 0 Access R/W R/W Bit 15 Symbol reserved Reset 0 Access R/W R/W Bit 7 Symbol Reset 1 Access R/W R/W Table 21: Bit ...

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Philips Semiconductors Bit 15 Symbol reserved Reset 0 Access R Bit 7 Symbol Reset 0 Access R Table 23: Bit 10.2.3 HcFmNumber register (R: 0FH) The HcFmNumber register is a 16-bit counter. It ...

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Philips Semiconductors Bit 7 Symbol Reset 0 Access R Table 25: Bit 10.2.4 HcLSThreshold register (R/W: 11H/91H) The HcLSThreshold register contains an 11-bit value used by the HC to determine whether to commit to ...

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Philips Semiconductors Table 27: Bit 10.3 HC Root Hub registers All registers included in this partition are dedicated to the USB Root Hub, which is an integral part of the HC although it is ...

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Philips Semiconductors Table 28: HcRhDescriptorA register: bit description Bit 31 Symbol Reset IS Access R/W R/W Bit 23 Symbol Reset 0 Access R/W R/W Bit 15 Symbol reserved Reset 0 Access R Bit 7 Symbol Reset 0 Access R Table ...

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Philips Semiconductors Table 29: Bit 10.3.2 HcRhDescriptorB register (R/W: 13H/93H) The HcRhDescriptorB register is the second register of two describing the characteristics of the Root Hub. These fields are written during initialization ...

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Philips Semiconductors Bit 7 Symbol Reset N/A N/A Access R Table 31: Bit 10.3.3 HcRhStatus register (R/W: 14H/94H) The HcRhStatus register is divided into two parts. The lower ...

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Philips Semiconductors Bit 15 Symbol DRWE Reset 0 Access R/W Bit 7 Symbol Reset 0 Access R Table 33: Bit 9397 750 13963 Product data ...

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Philips Semiconductors 10.3.4 HcRhPortStatus[1:2] (R/W [1]:15H/95H, [2]: 16H/96H) The HcRhPortStatus[1:2] register is used to control and report port events on a per-port basis. NumberDownstreamPorts represents the number of HcRhPortStatus registers that are implemented in hardware. The lower word is used ...

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Philips Semiconductors Table 35: Bit 9397 750 13963 Product data HcRshPortStatus[1:2] register: bit description Symbol Description PSSC PortSuspendStatusChange: This bit is set when the full resume sequence has been completed. This sequence includes ...

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Philips Semiconductors Table 35: Bit 9397 750 13963 Product data HcRshPortStatus[1:2] register: bit description Symbol Description PPS On read—PortPowerStatus: This bit reflects the port power status, regardless of the type of power switching implemented. ...

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Philips Semiconductors Table 35: Bit 9397 750 13963 Product data HcRshPortStatus[1:2] register: bit description Symbol Description PSS On read—PortSuspendStatus: This bit indicates whether the port is suspended or in the resume sequence set by a ...

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Philips Semiconductors 10.4 HC DMA and interrupt control registers 10.4.1 HcHardwareConfiguration register (R/W: 20H/A0H) Code (Hex): 20 — read Code (Hex): A0 — write Table 36: HcHardwareConfiguration register: bit allocation Bit 15 Symbol reserved Reset 0 Access R/W R/W Bit ...

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Philips Semiconductors Table 37: Bit 10.4.2 HcDMAConfiguration register (R/W: 21H/A1H) Code (Hex): 21 — read Code (Hex): A1 — write Table 38: HcDMAConfiguration register: bit allocation Bit 15 Symbol Reset 0 Access R/W R/W Bit 7 Symbol ...

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Philips Semiconductors Table 39: Bit 10.4.3 HcTransferCounter register (R/W: 22H/A2H) This register holds the number of bytes of a PIO or DMA transfer. For a PIO transfer, the number of bytes being read or written to the ...

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Philips Semiconductors After this register (24H to read) is read, the bits that are active will not be reset, until logic 1 is written to the bits in this register (A4H to write) to clear it. To clear all the ...

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Philips Semiconductors Table 43: Bit 10.4.5 Hc PInterruptEnable register (R/W: 25H/A5H) The bits 6:0 in this register are the same as those in the Hc PInterrupt register. They are used together with bit 0 of the HcHardwareConfiguration ...

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Philips Semiconductors Table 45: Bit 10.5 HC miscellaneous registers 10.5.1 HcChipID register (R: 27H) Read this register to get the ID of the ISP1160 silicon chip. The higher byte stands ...

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Philips Semiconductors Table 47: Bit 10.5.2 HcScratch register (R/W: 28H/A8H) This register is for the HCD to save and restore values when required. Code (Hex): 28 — read Code (Hex): A8 — write Table 48: HcScratch register: ...

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Philips Semiconductors 10.6 HC buffer RAM control registers 10.6.1 HcITLBufferLength register (R/W: 2AH/AAH) Write to this register to assign the ITL buffer size in bytes: ITL0 and ITL1 are assigned the same value. For example, if HcITLBufferLength register is set ...

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Philips Semiconductors Bit 7 Symbol Reset 0 Access R/W R/W Table 55: Bit 10.6.3 HcBufferStatus register (R: 2CH) Code (Hex): 2C — read Table 56: HcBufferStatus register: bit allocation Bit 15 Symbol Reset 0 Access R Bit ...

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Philips Semiconductors Table 58: HcReadBackITL0Length register: bit allocation Bit 15 Symbol Reset 0 Access R Bit 7 Symbol Reset 0 Access R Table 59: Bit 10.6.5 HcReadBackITL1Length register (R: 2EH) This register’s value stands for the current ...

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Philips Semiconductors Table 62: HcITLBufferPort register: bit allocation Bit 15 Symbol Reset 0 Access R/W R/W Bit 7 Symbol Reset 0 Access R/W R/W Table 63: Bit The HCD must set the byte count into the HcTransferCounter ...

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Philips Semiconductors The HCD must set the byte count into the HcTransferCounter register and check the HcBufferStatus register before reading from or writing to the buffer. The HCD must write the command (41H to read, C1H to write) once only, ...

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Philips Semiconductors 11. Power supply The ISP1160 can operate at either 3.3 V. When using the ISP1160’s power supply input, only V connected to the 5 V power supply. An application with a 5 ...

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Philips Semiconductors 13. Power-on reset (POR) When V will be typically (600 ns to 1000 ns) how fast V external power supply circuit. To give a better view of the functionality, V CC(POR) internal POR pulse will not react and ...

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Philips Semiconductors 14. Limiting values Table 66: Absolute maximum ratings In accordance with the Absolute Maximum Rating System (IEC 60134). Symbol Parameter V supply voltage to pin V CC(5V0) V supply voltage to pin V CC(3V3) V input voltage I ...

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Philips Semiconductors 16. Static characteristics Table 68: Static characteristics; supply pins specified. Symbol Parameter internal regulator output REG(3V3) I operating supply ...

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Philips Semiconductors Table 70: Static characteristics: analog I/O pins D and Symbol Parameter Input levels V differential input sensitivity DI V differential common mode voltage ...

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Philips Semiconductors 17. Dynamic characteristics Table 71: Dynamic characteristics Symbol Parameter Reset t pulse width on input RESET_N crystal oscillator running W(RESET_N) Crystal oscillator f crystal ...

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Philips Semiconductors 17.1 Programmed I/O timing Table 73: Dynamic characteristics: programmed interface timing Symbol Parameter t address set-up time before AS WR_N HIGH t address hold time after WR_N HIGH AH Read timing t first RD_N/WR_N after A0 HIGH SHSL ...

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Philips Semiconductors CS_N A0 RD_N WR_N data D [ 15:0 ] valid Fig 35. Programmed interface timing. 17.2 DMA timing 17.2.1 Single-cycle DMA timing Table 74: Dynamic characteristics: single-cycle DMA timing Symbol Parameter Read/write ...

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Philips Semiconductors Fig 36. Single-cycle DMA timing. 17.2.2 Burst mode DMA timing Table 75: Dynamic characteristics: burst mode DMA timing Symbol Parameter Read/write timing (for 4-cycle and 8-cycle burst mode) t WR_N/RD_N LOW pulse width RLRH t WR_N/RD_N HIGH to ...

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Philips Semiconductors DREQ t RHSH t SLAL DACK_N RD_N or WR_N Fig 37. Burst mode DMA timing. 17.2.3 External EOT timing for single-cycle DMASETUP Fig 38. External EOT timing for single-cycle DMA. 17.2.4 External EOT timing for burst mode DMA ...

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Philips Semiconductors 18. Application information 18.1 Typical interface circuit 5 V 3.3 V SH7709 3 15 CS5 RD_N RD/WR_N DREQ0 DACK0_N 5 V CLKOUT EXTAL IRQ2 XTAL PTC0 PTC1 EXTAL2 32 kHz XTAL2 ...

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Philips Semiconductors • • • • Remark: SH7709’s system clock input is for reference only. Refer to SH7709’s specification for its actual use. The ISP1160 can work under either 3 5.0 V power supply; however, its internal core ...

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Philips Semiconductors MECHANISM CONTROL TASK IMAGE PROCESSING TASKS FILE MANAGEMENT PRINTER UI/CONTROL OS DEVICE DRIVERS MASS STORAGE CLASS DRIVER PRINTING CLASS DRIVER RISC ROM RAM LEN CONTROL Fig 41. The ISP1160 software model for DSC application. 19. Test information The ...

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Philips Semiconductors 20. Package outline LQFP64: plastic low profile quad flat package; 64 leads; body 1 pin 1 index DIMENSIONS (mm are the original ...

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Philips Semiconductors LQFP64: plastic low profile quad flat package; 64 leads; body 1 pin 1 index DIMENSIONS (mm are the original dimensions) A UNIT ...

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Philips Semiconductors 21. Soldering 21.1 Introduction to soldering surface mount packages This text gives a very brief insight to a complex technology. A more in-depth account of soldering ICs can be found in our Data Handbook IC26; Integrated Circuit Packages ...

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Philips Semiconductors • • During placement and before soldering, the package must be fixed with a droplet of adhesive. The adhesive can be applied by screen printing, pin transfer or syringe dispensing. The package can be soldered after the adhesive ...

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Philips Semiconductors [3] [4] [5] [6] [7] [8] [9] 22. Revision history Table 77: Revision history Rev Date CPCN Description 05 20041224 200412019 Product data (9397 750 13963) Modifications: • • • 04 20030704 - Product data (9397 750 11371) ...

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Philips Semiconductors 23. Data sheet status [1] Level Data sheet status Product status I Objective data Development II Preliminary data Qualification III Product data Production [1] Please consult the most recently issued data sheet before initiating or completing a design. ...

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Philips Semiconductors Contents 1 General description . . . . . . . . . . . . . . . . . . . . . . 1 2 Features . . . . . . . . . ...