FT8U245AM

FT8U245AM USB FIFO - Fast Parallel Data Transfer IC FEATURES • • • • • Single Chip Fast Data Transfer Solution Send / Receive Data over USB at up to 1 M Bytes / sec 384 byte FIFO Transmit buffer / 128 byte FIFO receive buffer for high data throughput Simple interface to CPU or MCU bus No in-depth knowledge of USB required as all USB Protocol is handled automatically within the I.C. • FTDI’s Virtual COM port drivers eliminate the need for USB driver development in most cases. • • • • Compact 32 pin ( 7mm x 7mm ) MQFP package Integrated 6MHz - 48MHz Clock Multiplier aids FCC and CE compliance Integrated 3.3v Regulator – No External Regulator Required 4.4v .. 5.25v Single Supply Operation • • • • UHCI / OHCI Compliant USB 1.1 Specification Compliant USB VID, PID, Serial Number and Product Description Strings in external E2PROM. Virtual COM Port Drivers for – Windows 98 and Windows 98 SE Windows 2000 Windows Millennium ** Apple iMAC ** Linux ** Application Areas USB ISDN and ADSL Modems High Speed USB Ù PDA Communications USB I/F for Digital Cameras USB I/F for MP3 players Ù USB data transfer cables USB Ù USB null-modem cables USB High Speed USB Instrumentation GENERAL DESCRIPTION The FT8U245AM provides an easy cost-effective method of transferring data to / from a peripheral and a host P.C. at up to 8 Million bits ( 1 Megabyte ) per second. It’s simple FIFO-like design makes it easy to interface to any CPU ( MCU ) either by mapping the device into the Memory / IO map of the CPU, using DMA or controlling the device via IO ports. To send data from the peripheral to the host P.C. simply write the byte wide data into the device when the transmitter empty status bit is not active. If the ( 384 byte ) transmit buffer fills up, the device de-asserts transmit empty in order to stop further data being written to the device until some of the FIFO data has been transferred over USB. When the host P.C. sends data to the peripheral over USB, the device will assert the receiver full status bit to let the peripheral know that data is available. The peripheral then reads the data until the receiver full status bit goes inactive, indicating no more data is available to read. By using FTDI’s virtual COM Port drivers, the peripheral looks like a standard COM Port to the application software. Commands to set the baud rate are ignored – the device always transfers data at it’s fastest rate regardless of the application’s baud rate setting. Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change Figure 1 – FT8U245AM Block Diagram ( Simplified ) VCC 3V3OUT 3.3 Volt LDO Regulator FIFO Receive Buffer 128 Bytes USBDP USB Transceiver USBDM Serial Interface Engine ( SIE ) USB Protocol Engine FIFO Controller D0 D1 D2 D3 D4 D5 D6 D7 RD# WR RXF# TXE# USB DPLL FIFO Transmit Buffer 384 Bytes EEREQ# EEGNT# XTOUT 6MHZ Oscillator XTIN x8 Clock Multiplier 48MHz GND RESET# EEPROM Interface EECS EESK EEDATA 12MHz TEST RCCLK Figure 2 – FT8U245AM I.C. Pinout RCCLK EECS AVCC AGND XTOUT XTIN VCC 32 EESK EEDATA VCC RESET# TEST 3V3OUT USBDP USBDM 8 9 1 25 24 D1 D2 D3 D4 D5 D6 D7 17 16 GND FTDI FT245AM XXYY EEREQ# EEGNT# VCC GND RXF# TXE# Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change RD# WR D0 FT8U245AM - FUNCTIONAL BLOCK DESCRIPTION • 3.3V LDO Regulator The 3.3V LDO Regulator generates the 3.3 volt reference voltage for driving the USB transceiver cell output buffers. It requires an external decoupling capacitor to be attached to the 3V3OUT regulator output pin. • USB Transceiver The USB Transceiver Cell provides the USB 1.1 full-speed physical interface to the USB cable. The output drivers provide 3.3 volt level slew rate control signalling, whilst a differential receiver and two single ended receivers provide USB data in, SEO and USB Reset condition detection. • USB DPLL The USB DPLL cell locks on to the incoming NRZI USB data and provides separate recovered clock and data signals to the SIE block. • 6MHz Oscillator The 6MHz Oscillator cell generates a 6MHz reference clock input to the X8 Clock multiplier from an external 6MHz crystal or ceramic resonator. • X8 Clock Multiplier The X8 Clock Multiplier takes the 6MHz input from the Oscillator cell and generates a 12MHz reference clock for the SIE, USB Protocol Engine and UART FIFO controller blocks. It also generates a 48MHz reference clock for the USB DPPL and the Baud Rate Generator blocks. • Serial Interface Engine ( SIE ) The Serial Interface Engine ( SIE ) block performs the Parallel to Serial and Serial to Parallel conversion of the USB data. In accordance to the USB 1.1 specification, it performs bit stuffing / un-stuffing and CRC5 / CRC16 generation / checking on the USB data stream. • USB Protocol Engine The USB Protocol Engine manages the data stream from the device USB control endpoint. It handles the low level USB protocol ( Chapter 9 ) requests generated by the USB host controller and the commands for controlling the functional parameters of the UART. • Fifo Receive Buffer ( 128 bytes ) Data sent from the USB Host to the FIFO via the USB data out endpoint is stored in the FIFO Receive Buffer and is removed from the buffer by reading the FIFO contents using RD#. Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change • FIFO Transmit Buffer ( 384 bytes ) Data written into the FIFO using WR# is stored in the FIFO Transmit Buffer. The Host removes Data from the FIFO Transmit Data by sending a USB request for data from the device data in endpoint. • FIFO Controller The FIFO Controller handles the transfer of data between the external FIFO interface pins and the FIFO Transmit and Receive buffers. • EEPROM Interface The FT8U245AM uses an external 93C46 EEPROM to customise the USB VID, PID, Serial Number and Strings of the FT8U245AM for OEM applications. The FT8U245 Virtual Com Port Drivers rely on a unique device serial number for to bind a unique virtual COM port to each individual device. Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change Table 1 - FT8U245AM - PINOUT DESCRIPTION Pin # 7 8 6 27 28 31 4 32 1 2 5 25 24 23 22 21 20 19 18 16 Signal USBDP USBDM 3V3OUT XTIN XTOUT RCCLK RESET# EECS EESK EEDATA TEST D0 D1 D2 D3 D4 D5 D6 D7 RD# Type I/O I/O OUT IN OUT I/O IN I/O I/O I/O IN I/O I/O I/O I/O I/O I/O I/O I/O IN Description USB Data Signal Plus – Requires 1.5k pull-up to 3V3OUT USB Data Signal Minus 3.3 volt Output from integrated regulator Input to 6MHz Crystal Oscillator Cell Output from 6MHz Crystal Oscillator Cell RC timer – used to guarantee clock stability on exiting sleep mode. Clamped low during reset or sleep condition. Resets entire device using external RC network Optional EEPROM – Chip Select Optional EEPROM – Clock Optional EEPROM – Data I/O Puts device in i.c. test mode – must be tied to GND Bi-directional Data Bus Bit # 0 Bi-directional Data Bus Bit # 1 Bi-directional Data Bus Bit # 2 Bi-directional Data Bus Bit # 3 Bi-directional Data Bus Bit # 4 Bi-directional Data Bus Bit # 5 Bi-directional Data Bus Bit # 6 Bi-directional Data Bus Bit # 7 Enables Current FIFO Data Byte on D0..D7.when low. Fetches the next FIFO Data Byte ( if available ) from the Receive FIFO Buffer when RD# goes from low to high. Writes the Data Byte on the D0..D7 into the Transmit FIFO Buffer when WR goes from high to low. When high, do not write data into the FIFO. When low, data can be written into the FIFO by strobing WR high then low. When high, do not read data from the FIFO. When low, there is data available in the FIFO which can be read by strobing RD# low then high again. Requests the EEPROM contents to be accessed via the Data Bus. When low, allows the EEPROM contents to be accessed via the Data Bus. Device - +4.4 volt to +5.25 volt Power Supply Pins Device – Ground Supply Pins Device - Analog Power Supply for the internal x8 clock multiplier Device - Analog Ground Supply for the internal x8 clock multiplier 15 14 12 WR TXE# RXF# IN OUT OUT 11 10 3,13,26 9.17 30 29 EEREQ# EEGNT# VCC GND AVCC AGND IN OUT PWR PWR PWR PWR Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change FT8U245AM TIMING DIAGRAM – FIFO READ CYCLE T6 T5 RXF# T1 T2 RD# T3 T4 D0..D7 valid data Time T1 T2 T3 T4 T5 T6 Description RD Active Pulse Width RD to RD Pre-Charge Time RD Active to Valid Data Valid Data Hold Time from RD inactive RD Inactive to RXF# RXF inactive after RD cycle Min 50 50 Max Unit ns ns 30 10 5 80 25 ns ns ns ns Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change FT8U245AM TIMING DIAGRAM – FIFO WRITE CYCLE T12 T11 TXE# T7 T8 WR T10 T9 D0..D7 valid data Time T7 T8 T9 T10 T11 T12 Description WR Active Pulse Width WR to WR Pre-Charge Time Data Setup Time before WR inactive Data Hold Time from WR inactive WR Inactive to TXE# TXE inactive after RD cycle Min 50 50 Max Unit ns ns 20 10 5 80 25 ns ns ns ns Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change Figure 3. FT8U245AM - PACKAGE DESCRIPTION – QFP 7mm x 7mm 9 7 7 9 32 Pin # 1 0.8 1 12o +/- 1o 1.4 +/- 0.05 0.37 +/- 0.07 1.60 MAX 0.09 Min 0.2 Max 0.25 0.35 +/- 0.05 0.09 Min 0.16 Max 0.05 Min 0.15 Max 0.2 Min 0.6 +/- 0.15 All dimensions in millimetres Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change Absolute Maximum Ratings Storage Temperature ……………………………………………………. Ambient Temperature ( Power Applied )……………………………….. VCC Supply Voltage ……………………………………………….…….. DC Input Voltage - Inputs ……………………………………………….. DC Input Voltage - High Impedance Bidirectionals …………………… DC Output Current – Outputs …………………………………………… DC Output Current – Low Impedance Bidirectionals …………………. Power Dissipation ………………………………………………………… -65 C to + 150 C 0 C to + 70 C -0.5v to +6.00v -0.5v to VCC + 0.5v -0.5v to VCC + 0.5v 24mA 24mA 500mW o o o o DC Characteristics ( Ambient Temperature = 0 .. 70 Degrees C ) Description VCC Icc1 Icc2 Ioh1 Iol1 Voh1 Vol1 VDif VCom URxt UVh UVl Operating Supply Voltage Operating Supply Current Operating Supply Current Digital IO Pins Source Current Digital IO Pins Sink Current Input Voltage Threshold ( Low ) Input Voltage Threshold ( High ) USB Differential Input Sensitivity USB Differential Common Mode USB Single Ended Rx Threshold USB IO Pins Static Output ( Low ) USB IO Pins Static Output ( High ) Min 4.4 Max 5.25 50 250 Units v mA uA mA mA Conditions Normal Operation USB Suspend Voh = VCC – 0.5v Vol = + 0.5v 4 4 0.6 2.7 0.2 0.8 0.8 2.5 2.0 0.3v 2.8 v v v v v Rl = 1.5k to 3.6v Rl = 15k to GND Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change Disclaimer © Future Technology Devices International Limited – 1999, 2000 Neither the whole nor any part of the information contained in, or the product described in this manual, may be adapted or reproduced in any material or electronic form without the prior written consent of the copyright holder. This product and its documentation are supplied on an as is basis and no warranty as to their suitability for any particular purpose is either made or implied. Future Technology Devices International Ltd. will not accept any claim for damages howsoever arising as a result of use or failure of this product. Your statutory rights are not affected. This product or any variant of it is not intended for use in any medical appliance, device or system in which the failure of the product might reasonably be expected to result in personal injury. This document provides preliminary information that may be subject to change without notice. Contact Information Future Technology Devices Intl. Limited St. George’s Studios 93/97 St. George’s Road Glasgow G3 6JA, UK Telephone : Fax : Email : Internet : +44 ( 0 ) 141 353 2565 +44 ( 0 ) 141 353 2656 support@ftdi.co.uk http://www.ftdi.co.uk Agents and Sales Representatives Please visit our internet site for the latest contact details of our Agents and Sales Representatives world-wide. Future Technology Devices Intl. FT8U245AM Preliminary Information Rev 0.9 – Subject to Change Appendix A USB Device Descriptors USB Device Descriptors Note: E - replaced by E2Rom Value, C - modified by configuration option {* device descriptor *} LABEL : Device_Des; 0010 0011 0012 0014 0015 0016 0017 12 01 10 01 00 00 00 08 Val Val Val Val Val Val Val : : : : : : : Device_Len;{length of this descriptor in bytes} $01;{Device descriptor type} $10,$01;{USB Spec rev 1.10} $00;{Device class ?} $00;{Device subclass ?} $00;{Device protocol ?} Max_Length;{maximum packet size} LABEL : Device_Des_Vendor; E E 0018 03 04 001A 01 60 Val : $03,$04;{Vendor ID FTDI} Val : $01,$60;{product number 6001} LABEL : Device_Des_Vendor_End; E 001C 001E 001F 0020 0021 00 02 01 02 03 01 Val Val Val Val Val : : : : : $00,$02;{device release number 02.00} $01;{index of string descriptor describing manufacturer} $02;{index of string descriptor describing product} $03;{index of string descriptor describing serial number} $01;{number of possible configurations} {* end of device descriptor *} LABEL : Device_Des_End; LABEL : Config_Des; {* configuration descriptor *} 0022 0023 0024 0026 0027 0028 EC 0029 E 002A 09 02 20 00 01 01 00 80 2D Val Val Val Val Val Val Val Val : : : : : : : : $09;{length of this descriptor in bytes} $02;{Configuration descriptor} Config_Len,$00;{length of data returned for all things} $01;{number of interfaces supported by this configuration} $01;{configuration value} $00;{index of string descriptor describing this configuration} 10000000b;{configured as bus powered and not remote wakeup} 45;{maximum power in 2 mA ie 90mA for now} {* end of configuration descriptor *} LABEL : Interface_Des; {* interface descriptor *} 002B 002C 002D 002E 002F 0030 0031 0032 0033 09 04 00 00 02 FF FF FF 02 Val Val Val Val Val Val Val Val Val : : : : : : : : : $09;{length of this descriptor in bytes} $04;{Interface descriptor} $00;{interface number} $00;{alternate setting} $02;{number of endpoints excluding 0 = 1} $ff;{class code} $ff;{subclass} $ff;{protocol code} $02;{index of string descriptor describing this interface} {* end of interface descriptor *} LABEL : Interface_Des_End; LABEL : Endpoint_Des; LABEL : Endpoint3_Des_End; 0034 0035 0036 0037 0038 003A 07 05 81 02 40 00 00 Val Val Val Val Val Val : : : : : : $07;{length of this descriptor in bytes} $05;{End point descriptor} 10000001b;{in endpoint at address 1} 00000010b;{attribute as bulk} 64,$00;{maximum packet size} $00;{interval for polling endpoint for data transfers} LABEL : Endpoint3_Des; {* end point descriptor *} 003B 003C 003D 003E 003F 0041 07 05 02 02 40 00 00 Val Val Val Val Val Val : : : : : : $07;{length of this descriptor in bytes} $05;{End point descriptor} 00000010b;{out endpoint at address 2} 00000010b;{attribute as bulk} 64,$00;{maximum packet size} $00;{interval for polling endpoint for data transfers} LABEL : Endpoint_Des_End; LABEL : Config_Des_End; LABEL : Str0_Des; 0042 0043 0044 LABEL : 04 Val : Str0_Len; {length of string descriptor} 03 Val : $03; {type string} 09 04 Val : $09,$04; {language ID 0009 English} Str0_Des_End; LABEL : Str1_Des; E 0046 E 0047 E 0048 E 004A E 004C E 004E LABEL : 0A Val : 03 Val : 46 00 Val : 54 00 Val : 44 00 Val : 49 00 Val : Str1_Des_End; Str1_Len; {length of string descriptor} $03; {type string} 'F',$00; 'T',$00; 'D',$00; 'I',$00; LABEL : Str2_Des; E 0050 E 0051 E 0052 E 0054 E 0056 E 0058 E 005A E 005C E 005E E 0060 E 0062 E 0064 E 0066 E 0068 E 006A E 006C LABEL : 1E Val : 03 Val : 55 00 Val : 53 00 Val : 42 00 Val : 20 00 Val : 3C 00 Val : 2D 00 Val : 3E 00 Val : 20 00 Val : 53 00 Val : 65 00 Val : 72 00 Val : 69 00 Val : 61 00 Val : 6C 00 Val : Str2_Des_End; Str2_Len; {length of string descriptor} $03; {type string} 'U',$00; 'S',$00; 'B',$00; ' ',$00; '',$00; ' ',$00; 'S',$00; 'e',$00; 'r',$00; 'i',$00; 'a',$00; 'l',$00; LABEL : Str3_Des; E 006E E 006F E 0070 E 0072 E 0074 E 0076 E 0078 E 007A E 007C E 007E LABEL : 12 Val : 03 Val : 31 00 Val : 32 00 Val : 33 00 Val : 34 00 Val : 35 00 Val : 36 00 Val : 37 00 Val : 38 00 Val : Str3_Des_End; Str3_Len; $03; '1',00; '2',00; '3',00; '4',00; '5',00; '6',00; '7',00; '8',00; {serial number string} {type string} Appendix B EEPROM Data Structure E2Rom Data example 0000 0002 0004 0006 0008 0009 000A 000C 000E 000F 0010 0011 0012 0013 00 03 01 00 A0 2D 00 00 94 0C A0 34 D4 12 00 04 60 02 00 00 Val Val Val Val Val Val Val Val VAL Val VAL Val VAL Val : : : : : : : : : : : : : : $00,$00;{Configuration value} $03,$04;{Vendor ID FTDI} $01,$60;{product number 6001} $00,$02;{device release number} 10100000b; {config descriptor value bus powered and remote wakeup} 45; {max power = value * 2 mA} $00,$00;{reserved} $00,$00;{reserved} PTR_ManStringDes; ManStringDes_Len; {length of string descriptor} PTR_ProdStringDes; ProdStringDes_Len; {length of string descriptor} PTR_SerStringDes; SerStringDes_Len; LABEL : ManStringDes; 0014 0C 0015 03 0016 41 0018 6E 001A 64 001C 79 001E 73 LABEL : Val : ManStringDes_Len; Val : $03; {type string} 00 Val : 'A',$00; 00 Val : 'n',$00; 00 Val : 'd',$00; 00 Val : 'y',$00; 00 Val : 's',$00; ManStringDes_End; {length of string descriptor} LABEL : ProdStringDes; 0020 34 0021 03 0022 57 0024 6F 0026 6E 0028 64 002A 65 002C 72 002E 66 0030 75 0032 6C 0034 6C 0036 20 0038 55 003A 53 003C 42 003E 20 0040 3C 0042 2D 0044 3E 0046 20 0048 53 004A 65 004C 72 004E 69 0050 61 0052 6C LABEL : Val : ProdStringDes_Len; {length of string descriptor} Val : $03; {type string} 00 Val : 'W',$00; 00 Val : 'o',$00; 00 Val : 'n',$00; 00 Val : 'd',$00; 00 Val : 'e',$00; 00 Val : 'r',$00; 00 Val : 'f',$00; 00 Val : 'u',$00; 00 Val : 'l',$00; 00 Val : 'l',$00; 00 Val : ' ',$00; 00 Val : 'U',$00; 00 Val : 'S',$00; 00 Val : 'B',$00; 00 Val : ' ',$00; 00 Val : '',$00; 00 Val : ' ',$00; 00 Val : 'S',$00; 00 Val : 'e',$00; 00 Val : 'r',$00; 00 Val : 'i',$00; 00 Val : 'a',$00; 00 Val : 'l',$00; ProdStringDes_End; LABEL : SerStringDes; 0054 12 0055 03 0056 32 0058 32 005A 33 005C 34 005E 35 0060 36 0062 37 0064 38 LABEL : Val : SerStringDes_Len; Val : $03; {type string} 00 Val : '2',00; 00 Val : '2',00; 00 Val : '3',00; 00 Val : '4',00; 00 Val : '5',00; 00 Val : '6',00; 00 Val : '7',00; 00 Val : '8',00; SerStringDes_End; Val : $00,$00; {reserved for Checksum} 0066 00 00