MAX II Development Board Data Sheet July 2005, version 1.1 Features The MAX(R) II development board, included with the MAX II Development Kit, is a full-featured platform for evaluating MAX II device features and prototyping CPLD designs. Circuits are provided to allow users to measure MAX II power consumption and MAX II power-up timing. Memory, displays, and interfaces enable designers to begin the development or testing of custom CPLD designs. Circuits The MAX II development board contains the following circuits: Active I/O sense circuit--Allows users to load VCCINT and observe the effect on MAX II user I/O ramp times Power measuring circuit--Allows users to measure the stand-by and nominal power consumed by the MAX II device Schmitt trigger circuit--Allows users to generate a custom clock using the internal Schmitt trigger Components The MAX II development board contains the following components: MAX II EPM1270F256C5 device 66-MHz oscillator Temperature sensor Four user-definable push-button switches Four user-definable LEDs 16x2 character LCD SRAM Interfaces The MAX II development board contains the following interfaces: Altera Corporation DS-M29904-1.1 USB Interface V1.1 or V2.0 Type B connector 32-bit PCI edge connector Altera(R) expansion prototype header Prototyping area 1 MAX II Development Board General Description The MAX II development board provides a hardware platform designers can use to evaluate MAX II device features and to prototype CPLD designs. Components & Interfaces Figure 1 shows a top view of the board components and interfaces. Figure 1. MAX II Development Board Top View Altera Expansion Prototype Header 66 MHz Oscillator USB MAC Current Sensor LCD Push-button Switches USB Type B Connector User Definable LEDs SRAM Prototyping Area 2 Preliminary Active I/O Test Points PCI Quickswitches A/D Converter PCI Edge Connector Potentiometer Temperature Sensor Altera Corporation General Description Table 1 describes the components on the board and the interfaces it supports. Table 1. MAX II Development Board Components & Interfaces Component/Interface Type Board Designation Description Circuits Active I/O sensor Circuit Active I/O test points Circuit for investigating MAX II power optimization Current sensor Circuit U2, U19, U23 Power measuring circuit Schmitt trigger Circuit R13, C8 RC circuit for investigating the internal Schmitt trigger in MAX II devices Components 66-MHz oscillator Clock U3 Main clock for MAX II board Temperature sensor I/O U1 Allows designer to measure board temperature User push-button switches Input S1, S2, S3, S4 User-definable push-button switches User LEDs Output LED1, LED2, LED3, LED4 User-definable LEDs Status LEDs Status LED5, LED6, LED7, LED8, LED9, LED10 Indicate which components are receiving power LCD I/O LCD1 On-board LCD SRAM Memory U5 1 Mbit of SRAM PCI quickswitches I/O U7, U8, U9, U10, U11 Convert 5.0-V PCI signals into 3.3-V signals Potentiometer I/O POT1 Adjusts the load on the VC C I N T plane USB I/O U13 Universal serial bus media access controller PCI I/O B1, B62, A1, A62 PCI edge connector Altera Expansion Prototype Header I/O J3, J4, J5 Daughter card header Prototyping area I/O PA1 Allows designer to add custom components to the MAX II development board Interfaces Environmental Requirements The MAX II development board must be stored between -40 C and 100 C. The recommended operating temperature is between 0 C and 55 C. 1 Altera Corporation The MAX II development board can be damaged without proper anti-static handling. 3 Preliminary MAX II Development Board Using the Board This section provides information on using the MAX II development board. Apply Power Power can be applied to the board from the USB or PCI bus. Jumper J8 controls which source supplies power. If the shunt is on pins 1 and 2, the board will be powered via the USB bus. If the shunt is on pins 2 and 3, the board will be powered via the PCI bus. Pin 1 of J8 is the pin closest to the LCD. When the board is powered up, the LED power indicators (LEDs 5, 6, 7, 8, 9, and 10) will illuminate. Program the MAX II Device The MAX II device on the MAX II development board can be programmed using the Quartus(R) II software. To program the board, the designer must supply power as indicated above and then connect the ByteBlasterTM cable to the 10-pin JTAG header on the board (J2). More detail on programming MAX II devices is available in the MAX II Development Kit Getting Started User Guide and Quartus II Help. w 4 Preliminary The Quartus II software default setting in the Unused Pins tab leaves unused pins as outputs, driving ground. When compiling designs that target Altera development boards, change this setting so that unused pins act as inputs and are tri-stated. The reason for this change is that components on the board may be damaged by having GND signals driven onto pins that drive VCC. However, if you set these unused pins to behave as inputs and they are tri-stated, then they will not damage the board. To change this option in the Quartus II software, select Settings (Assignments menu). In the menu on the right, click Device, then click Device and Pin Options. In the Device & Pin Options dialog box, click the Unused Pins tab. Ensure this option is set to As inputs, tri-stated. See Figure 2. Altera Corporation Functional Description Figure 2. Quartus II Device & Pin Options Dialog Box Functional Description Altera Corporation This section describes the components of the MAX II development board. Figure 3 shows a block diagram of the board. See Figure 1 on page 2 for a photograph of the board, which shows the names and locations of all board features. 5 Preliminary MAX II Development Board Figure 3. MAX II Development Board Block Diagram User Pushbuttons SPI LEDs Temperature Sensor ADC 8 Bits 4 Channels 4 Inputs 4 Outputs Current Sensor SPI Bus Amplifier Power Supply Reg Reg LCD Display 16 x 2 Character VCCINT Interrupt with Ramp Control Display Bus MAX II EPM1270F256C5 Device Power Distribution Controls Address Bus USB Interface Power Indicator FIFO Bus Data Bus SRAM 128K x 8 PCI Bus Power You can power the MAX II development board from either the PCI bus or the USB bus. If you are not using the board in the PCI slot of a PC, then you must power the board from the USB bus. Jumper J8 is used to select which bus powers the board. If the shunt is on pins 1 and 2, the board will be powered via the USB bus. If the shunt is on pins 2 and 3, the board will be powered via the PCI bus. Pin 1 of J8 is the pin closest to the LCD. The PCI bus or the USB bus routes the power to six different regulators, which power individual board components. The MAX II device is powered from either a 2.5-V or a 3.3-V power supply. You select which supply voltage to use (for VCCINT) by using jumper J9. The slew rate (or load) of VCCINT can be adjusted by the potentiometer (POT1). Power-Up Sequence When you apply power to the MAX II development board, the 5.0-V power supply powers up first, because it is the source for the 3.3-V/2.5-V power supply. The 3.3-V/2.5-V VCCINT supply powers up second. You can increase or decrease the rate at which the VCCINT supply comes up by 6 Preliminary Altera Corporation Functional Description increasing or decreasing the value of the potentiometer (POT1). The MAX II device enables the regulators, which supply power to the LCD, Altera Expansion Prototype Header, and memory device. The outputs from the MAX II device power the ADC and the temperature sensor because they require very little current. Those components power up last (and at roughly the same time) because they depend upon outputs of the MAX II device to get power. Figure 4 shows a block diagram of power distribution on the board. Altera Corporation 7 Preliminary MAX II Development Board Figure 4. Power Supply Distribution Block Diagram +5 V Voltage Regulator Voltage Regulator Voltage Regulator Power Controls Select Power Source USB +5 V Voltage Regulator 4 +5 V Voltage Regulator Memory USB MAC LCD Altera Expansion Prototype Header VCCINT PCI +5 V Power Interrupt Switch Ramp Circuit +3.3 V if Shorted Voltage Regulator VCCIO +2.5 V if Open 8 Preliminary Altera Corporation Functional Description Table 2 provides information on the MAX II development board voltage regulator. Table 2. Voltage Regulator Reference Information Parameter Definition Board References U14, U16, U17, U18, U20, U21 Part Number LP3982ILD-ADJ Device Description Adjustable linear voltage regulator Manufacturer National Semiconductor Manufacturer Web Site www.national.com Power Budget Table 3 shows the typical and maximum power requirements of the main components on the MAX II development board. Table 3. Power Usage of MAX II Development Board Components +3.3 V Description MFG MFG Part Number Quantity Typical Current (mA) Maximum Current (mA) MAX II device Altera EPM1270F256C5 1 N/A 225 SRAM Cypress CY7009B 1 5 70 LCD Crystalfontz CFAH1602B-NYA-JP 1 2 2 Oscillator ECS ECS-3953C-666-TR 1 25 25 ADC Maxim MAX1111 1 0.1 0.25 Current sensor Maxim MAX4072 2 0.1 0.25 Temperature sensor Maxim MAX6642 1 0.5 1 USB FTDI FT245BM 1 25 - Regulator National Semiconductor LM38982 6 0.1 0.27 Altera Corporation TOTAL [A] 0.376 TOTAL [W] 1.241 Total +5 V power [W] 1.880 Total watts (entire board) 1.88 9 Preliminary MAX II Development Board Table 4 shows the pin-outs for the power supply enable signals for each of the components on the board. Table 4. Power Supply Enable Pin-Outs Signal MAX II Pin V_LCD_ENA B3 V_MEM_ENA A2 V_SC_ENA B1 MAX II Device The MAX II device (EPM1270) on the board features 1270 logic elements (LEs) and 8 Kbit of user flash memory in a 256-pin FBGA package. f For more information on MAX II device features, see the MAX II Device Family Data Sheet section in the MAX II Device Handbook. Table 5 describes the features of the MAX II device. Table 5. MAX II Device Reference Item 10 Preliminary Description Logic Elements (LEs) 1,270 User Flash Memory 8 Kbit User I/O Pins 206 Board Reference U4 Internal Voltage Variable (2.5 V or 3.3 V) Altera Corporation Functional Description Clocks & Clock Distribution The main user clock on the board is the 66 MHz oscillator. Table 6 describes this component. Table 6. 66 MHz On-Board Oscillator Reference Item Description Board Reference U3 Part Number ECS-3953C-666 Device Description 66 MHz Crystal Oscillator Manufacturer ECS Inc. Manufacturer Web Site www.ecsxtal.com Table 7 lists the clocks available on the MAX II development board. There are four different clocks on the board. Table 7. Clock Signal Distribution Clock Source Destination 66 MHz Oscillator On-board oscillator (U3) MAX II device, pin H5 6 MHz Resonator On-board resonator (Y1) USB MAC (U13, pins 26 and 27) PCI Clock PCI edge connector MAX II device, pin H12 Altera Expansion Prototype Header Altera expansion header (J3, J4, J5) MAX II device, pin J5 Reset The MAX II device handles the reset for the board internally. The S1 push-button switch connects to the DEV_CLRn pin of the MAX II device, which may be a user-defined I/O or a reset input. Altera Corporation 11 Preliminary MAX II Development Board Board Components The following sections describe the development board components. Push-Button Switches The board has five user push-button switches (S1, S2, S3, S4, and S5). S1 connects to the DEV_CLRn pin of the MAX II device. S5 interrupts the MAX II VCCINT power supply. Table 8 describes the push-button switches. Table 8. Push-Button Switches Reference Item Description Board References S1, S2, S3, S4, S5 Part Number EVQPAC07K Device Description Push-button switches Manufacturer Panasonic Manufacturer Web Site www.panasonic.com Table 9 shows the pin-outs for the push-button switches. Table 9. Push-Button Switch Pin-Outs Signal Name 12 Preliminary Description MAX II Pin S1 Reset, DEV_CLRn M9 S2 User defined R14 S3 User defined T15 S4 User defined R16 S5 Power interrupt None Altera Corporation Board Components LEDs The MAX II development board has the following LEDs: Four user-definable LEDs that connect to outputs from the MAX II device Six power indicator LEDs, one for each main component on the board Table 10 describes the LEDs. Table 10. LED Reference Item Description Board References LED1, LED2, LED3, LED4, LED5, LED6, LED7, LED8, LED9, LED10 Part Number LTST-C150CKT Device Description LED Manufacturer Lite-on Industry Manufacturer Web Site www.liteon.com Table 11 shows the pin-outs for the LEDs. Table 11. LED Pin-Outs Signal Name Altera Corporation Description MAX II Pin LED1 User-defined T13 LED2 User-defined R13 LED3 User-defined P13 LED4 User-defined T12 LED5 LCD power indicator N/A LED6 SRAM power indicator N/A LED7 VC C I O power indicator N/A LED8 Altera Expansion Prototype Header power indicator N/A LED9 USB power indicator N/A LED10 VC C I N T power indicator N/A 13 Preliminary MAX II Development Board LCD The liquid crystal display (LCD) is a 16 x 2 character display from either Crystalfontz (CFAH1602B-NYA-JP) or AZD. Table 12 describes the Crystalfontz LCD. Table 12. Crystalfontz LCD Reference Item Description Board Reference LCD1 Part Number CFAH1602B-NYA-JP Device Description LCD Manufacturer Crystalfontz Manufacturer's Web Site www.crystalfontz.com Table 13 describes the AZD LCD. Table 13. AZD LCD Reference Item Board Reference Description LCD1 Part Number ACM1602-RN-GBS Device Description LCD Manufacturer AZD Manufacturer's Web Site www.az.azdisplays.com Table 14 shows the pin-outs for the LCD. Table 14. LCD Pin-Outs (Part 1 of 2) Signal Name 14 Preliminary Description MAX II Pin LCD_DB0 Data Bus B10 LCD_DB1 Data Bus C10 LCD_DB2 Data Bus D10 LCD_DB3 Data Bus A9 LCD_DB4 Data Bus B9 LCD_DB5 Data Bus C9 LCD_DB6 Data Bus D9 Altera Corporation Board Components Table 14. LCD Pin-Outs (Part 2 of 2) Signal Name LCD_DB7 Description MAX II Pin Data Bus A8 LCD_E Enable A10 LCD_RS Data/Instruction Select C11 LCD_RW Read/Write Select D11 Current Sensor Amplifier You measure current to the MAX II development board by using an on-board Maxim MAX4072 high-side current sense amplifier with a pair of 0.33- resistors in parallel as the sensing element. This has a maximum voltage drop of 41 mV at 250 mA. At high current levels, the resolution with an 8-bit converter is roughly 1 mA. The current sensor is located upstream from the regulators for the VCCINT and VCCIO voltages so that only one of the voltages is required to measure all of the current of the MAX II development board. The output of the Maxim MAX4072 amplifier feeds the analog-to-digital converter (ADC). See "Analog/Digital Converter" on page 16. The output of the ADC feeds the MAX II device. The current drawn by the MAX II device can also be determined by measuring the voltage across R109 or R113 (for VCCINT) and R95 or R99 (for VCCIO). The resistance value from the two 0.33- resistors in parallel is 0.165 . IVCCINT = (VR109/0.165) = (VR113/0.165) IVCCIO = (VR95/0.165) = (VR99/0.165) Table 15 describes the current sensor. Table 15. Current Sensor Reference Item Altera Corporation Description Board References U19, U23 Part Number MAX4072AUA Device Description Current Sense Amplifier Manufacturer Maxim Manufacturer Web Site www.maxim-ic.com 15 Preliminary MAX II Development Board Table 16 shows the pin-outs for the current sensor. Table 16. Current Sensor Pin-Outs Signal Name Description MAX II Pin GSEL_Int Gain Select for VC C I N T (U23) A4 GSEL_IO Gain Select for VC C I O (U19) D4 IO_V_ADC Enables power supply to the ADC and Current Sensors A13 Analog/Digital Converter The analog-to-digital converter (ADC) is a Maxim MAX1111 device. It has a Serial Peripheral Interface (SPI) that provides eight bits of resolution on four channels. It also provides the reference voltage for the current sensor amplifier. Table 17 describes the ADC. Table 17. 8-Bit, 4-Channel ADC Reference Item Description Board Reference U2 Part Number MAX1111 Device Description Analog-to-digital converter Manufacturer Maxim Manufacturer Web Site www.maxim-ic.com Table 18 shows the pin-outs for the ADC. Table 18. 8-Bit, 4-Channel ADC Pin-Outs Signal Name 16 Preliminary Description MAX II Pin ADC_CLK Clock D12 ADC_CSN Chip Select C12 ADC_DIN Data Input B12 ADC_DOUT Data Output A11 ADC_SHDN Three-level Shutdown Input B11 ADC_SSTRB Serial Strobe Output A12 IO_V_ADC Allows power to the ADC and Current Sensors A13 Altera Corporation Board Components Temperature Sensor The temperature sensor is a Maxim MAX6627 device. It uses an SPI interface to provide the temperature reading on the board or from a remote sensor diode. Remove the Q1 component from the board to use a remote sensor so the diode can be connected across J1. Table 19 describes the temperature sensor. Table 19. Temperature Sensor Reference Item Board Reference Description U1 Part Number MAX6627MKA-T Device Description Temperature Sensor Manufacturer Maxim Manufacturer Web Site www.maxim-ic.com Table 20 shows the pin-outs for the temperature sensor. Table 20. Temperature Sensor Pin-Outs Signal Name Description MAX II Pin TEMP_CSN Chip Select B14 TEMP_SCK Clock C13 TEMP_SDO Data Output A15 SRAM The board features 1 Mbit of SRAM. Table 21 describes the SRAM. Table 21. SRAM Reference Item Altera Corporation Description Board Reference U5 Part Number CY7C1019CV Device Description 128K x 8 SRAM Manufacturer Cypress Manufacturer Web Site www.cypress.com 17 Preliminary MAX II Development Board Table 22 shows the pin-outs for the SRAM. Table 22. SRAM Pin-Outs Signal Name 18 Preliminary Description MAX II Pin A0 Address input to SRAM T2 A1 Address input to SRAM T4 A2 Address input to SRAM P4 A3 Address input to SRAM R5 A4 Address input to SRAM N8 A5 Address input to SRAM R9 A6 Address input to SRAM T10 A7 Address input to SRAM P10 A8 Address input to SRAM R10 A9 Address input to SRAM P9 A10 Address input to SRAM T9 A11 Address input to SRAM P8 A12 Address input to SRAM T8 A13 Address input to SRAM T5 A14 Address input to SRAM R4 A15 Address input to SRAM R3 A16 Address input to SRAM R1 D0 Data to/from SRAM R6 D1 Data to/from SRAM N6 D2 Data to/from SRAM R7 D3 Data to/from SRAM N7 D4 Data to/from SRAM P7 D5 Data to/from SRAM T7 D6 Data to/from SRAM P6 D7 Data to/from SRAM T6 CEN Chip enable to SRAM N5 OEN Output enable to SRAM P5 WEN Write enable to SRAM R8 Altera Corporation Board Components USB MAC/PHY The USB MAC solution is from FTDI. This MAC supports USB versions 1.1 and 2.0 (High-speed only). If you want to use USB version 2.0, the EEPROM socket (J10) must be added to the board and populated with an EEPROM. The EEPROM should then be programmed using the utilities provided by FTDI. See the FTDI Chip web site at www.ftdichip.com for detailed instructions and for the required software and drivers. The footprint on the board is for the SAMTEC EEPROM socket, part number ICA-308-STT. The default configuration works for USB version 1.1. FTDI's VCOM drivers provide a simple method to interface the MAX II development board to a PC. The MAX II Development Kit provides an open-source reference design using these drivers. f For more information on this reference design, refer to the MAX II Development Kit Getting Started User Guide. Table 23 describes the USB MAC. Table 23. USB MAC Reference Item Board Reference Description U13 Part Number FT245BM Device Description USB MAC Manufacturer FTDI Manufacturer Web Site www.ftdichip.com Table 24 shows the pin-outs for the USB MAC. Table 24. USB MAC Pin-Outs (Part 1 of 2) Signal Name Altera Corporation Description MAX II Pin USB_D0 Data input A7 USB_D1 Data input B7 USB_D2 Data input C7 USB_D3 Data input D7 USB_D4 Data input A6 USB_D5 Data input B6 USB_D6 Data input C6 19 Preliminary MAX II Development Board Table 24. USB MAC Pin-Outs (Part 2 of 2) Signal Name USB_D7 Description MAX II Pin Data input D6 USB_RDN Read FIFO A5 USB_RXFN Data available in FIFO D5 USB_TXEN USB FIFO ready to receive data from MAX II device C5 USB_WR Write FIFO B5 USB_PWREN Power enable B4 USB_WU Send Immediate/Wake Up C4 USB_SK Clock Signal to EEPROM (1) C8 USB_CS EEPROM Chip Select (1) D8 USB_EEDATA EEPROM Data (1) B8 Note for Table 24: (1) PCI Edge Connector This signal is routed directly to the MAX II device and to the (unpopulated) EEPROM at J10 The MAX II development board features a PCI edge connector. The board can be used in either 3.3- or 5.0-V PCI slots. This functionality is possible because the quickswitches limit the voltage in 5.0-V systems. The board is also equipped with unpopulated resistors. You can populate these resistors and remove the quickswitches if the desired voltage is 3.3 V and the quickswitches are unwanted. The recommended method of operation in either 3.3- or 5.0-V systems is with the quickswitches in place. The MAX II Development Kit includes a reference design that implements Altera's pci_t32 MegaCore(R) function on the MAX II development board. See the MAX II Development Kit Getting Started User Guide for more details. Table 25 shows the pin-outs for the PCI edge connector. Table 25. PCI Edge Connector Pin-Outs (Part 1 of 3) Signal Name 20 Preliminary MAX II Pin PCI_AD[0] C14 PCI_AD[1] C15 PCI_AD[10] F12 PCI_AD[11] F13 PCI_AD[12] F15 Altera Corporation PCI Edge Connector Table 25. PCI Edge Connector Pin-Outs (Part 2 of 3) Signal Name Altera Corporation MAX II Pin PCI_AD[13] F16 PCI_AD[14] G12 PCI_AD[15] G13 PCI_AD[16] J16 PCI_AD[17] K12 PCI_AD[18] K13 PCI_AD[19] K14 PCI_AD[2] D13 PCI_AD[20] K15 PCI_AD[21] K16 PCI_AD[22] L11 PCI_AD[23] L12 PCI_AD[24] L16 PCI_AD[25] M13 PCI_AD[26] M14 PCI_AD[27] M15 PCI_AD[28] M16 PCI_AD[29] N13 PCI_AD[3] D14 PCI_AD[30] N14 PCI_AD[9] F11 PCI_CBEN[0] E15 PCI_CBEN[1] G14 PCI_CBEN[2] J15 PCI_CBEN[3] L15 PCI_CLK H12 PCI_DEVSELN H15 PCI_ENABLEN B16 PCI_FRAMEN J14 PCI_GNTN P15 PCI_IDSEL L13 PCI_INTAN N16 PCI_IRDYN J13 PCI_LOCKN K11 21 Preliminary MAX II Development Board Table 25. PCI Edge Connector Pin-Outs (Part 3 of 3) Signal Name MAX II Pin PCI_PAR G15 PCI_PERRN H13 PCI_REQN P14 PCI_RSTN J12 PCI_SERRN G16 PCI_STOPN H14 PCI_TRDYN H16 PCI_AD[31] N15 PCI_AD[4] D15 PCI_AD[5] D16 PCI_AD[6] E12 PCI_AD[7] E13 PCI_AD[8] E16 Altera Expansion Prototype Header The Altera expansion prototype header consists of three 0.1-inch headers: one 40-pin connector (J4), one 14-pin connector (J3), and one 20-pin connector (J5). These pins are arranged as shown in Figure 5. The only difference between a male and a female connector is the sex of the 0.1-inch headers. In Figure 5, NC signifies no connection. SC_40 to SC_0 are user I/O pins routed to the MAX II device. The SC_CLK2 pin is routed to GCLK1, one of two global clocks, in the MAX II device. 22 Preliminary Altera Corporation PCI Edge Connector Figure 5. Altera Expansion Prototype Header Pins J3 SC_36 SC_38 SC_RESET SC_29 SC_0 SC_31 SC_2 SC_33 SC_4 SC_35 SC_6 SC_37 SC_8 SC_39 SC_10 SC_12 SC_14 J5 3.3 V 3.3 V SC_OSC SC_CLK1 SC_CLK2 3.3 V 3.3 V 3.3 V 2 4 6 8 10 12 14 16 18 20 NC 1 3 5 7 9 11 13 15 17 19 5.0 V GND GND SC_16 GND SC_17 GND SC_18 GND SC_19 GND SC_21 GND SC_22 GND SC_24 GND SC_25 GND SC_27 GND SC_28 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 32 34 36 38 40 SC_34 NC 1 3 5 7 9 11 13 15 17 19 21 23 25 27 29 31 33 35 37 39 SC_32 2 4 6 8 10 12 14 SC_30 1 3 5 7 9 11 13 GND SC_40 J4 GND SC_1 SC_3 SC_5 SC_7 SC_9 SC_11 SC_13 SC_15 NC GND GND GND SC_20 GND SC_23 GND SC_26 SC_CARDSELn GND Table 26 shows the pin-outs for Altera expansion prototype header pins. Table 26. Altera Expansion Prototype Header Pin-Outs (Part 1 of 2) Signal Name Altera Corporation Location MAX II Pin SC_CARDSELn J4p38 H4 SC_CLK1 J5p11 L4 SC_CLK2 J5P13 J5 SC_OSC J5p9 L3 SC_RESETn J4p1 E5 SC_0 J4p3 C2 SC_1 J4p4 C3 SC_2 J4p5 D1 SC_3 J4p6 D2 SC_4 J4p7 D3 SC_5 J4p8 E1 SC_6 J4p9 E2 23 Preliminary MAX II Development Board Table 26. Altera Expansion Prototype Header Pin-Outs (Part 2 of 2) Signal Name 24 Preliminary Location MAX II Pin SC_7 J4p10 E3 SC_8 J4p11 E4 SC_9 J4p12 F1 SC_10 J4p13 F2 SC_11 J4p14 F3 SC_12 J4p15 F4 SC_13 J4p16 G1 SC_14 J4p17 G2 SC_15 J4p18 G3 SC_16 J4p21 G4 SC_17 J4p23 H1 SC_18 J4p25 H2 SC_19 J4p27 H3 SC_20 J4p28 J1 SC_21 J4p29 J2 SC_22 J4p31 J3 SC_23 J4p32 K1 SC_24 J4p33 K2 SC_25 J4p35 K3 SC_26 J4p36 K4 SC_27 J4p37 L1 SC_28 J4p39 L2 SC_29 J3p4 M1 SC_30 J3p5 M2 SC_31 J3p6 M3 SC_32 J3p7 M4 SC_33 J3p8 N1 SC_34 J3p9 N2 SC_35 J3p10 N3 SC_36 J3p11 P2 SC_37 J3p12 T11 SC_38 J3p13 N10 SC_39 J3p14 R11 SC_40 J3p3 J4 Altera Corporation Schmitt Trigger Circuit Schmitt Trigger Circuit The MAX II development board has an R-C circuit to allow designers to investigate the internal Schmitt trigger on MAX II I/O pins. Figure 6 shows the circuit. Figure 6. R-C Circuit RC CLK_CTRL Pin N11 RC CLK Pin P11 R13 Active I/O Test Points f C8 The MAX II development board provides four test points to allow the designer to analyze the timing of the MAX II device power-up and configuration. For more information on using the test points to analyze the MAX II device power up and configuration, see the MAX II Development Kit Getting Started User Guide. Table 27 shows the pin-outs for the signals in this circuit. Table 27. Signals Used as Test Points ID Prototype Section Altera Corporation Signal Description V_int 3.3 or 2.5 V +3.3-V/2.5-V power for the MAX II internal logic V_io 3.3 V 3.3-V supply for MAX II VC C I O GND GND Ground plane of MAX II development board Active IO MAX II pin P12 MAX II user I/O pin A prototype area consisting of an array of 120 0.1-inch holes is provided. This area can be used to add custom components to the MAX II development board. Connections to both the 3.3 V plane and ground plane of the MAX II board are included. The silk-screen text on the board indicates which holes are connected to which planes. All of the other holes are not connected to anything on the board. 25 Preliminary MAX II Development Board 101 Innovation Drive San Jose, CA 95134 (408) 544-7000 www.altera.com Applications Hotline: (800) 800-EPLD Literature Services: literature@altera.com 26 Preliminary Copyright (c) 2005 Altera Corporation. All rights reserved. Altera, The Programmable Solutions Company, the stylized Altera logo, specific device designations, and all other words and logos that are identified as trademarks and/or service marks are, unless noted otherwise, the trademarks and service marks of Altera Corporation in the U.S. and other countries. All other product or service names are the property of their respective holders. Altera products are protected under numerous U.S. and foreign patents and pending applications, maskwork rights, and copyrights. Altera warrants performance of its semiconductor products to current specifications in accordance with Altera's standard warranty, but reserves the right to make changes to any products and services at any time without notice. Altera assumes no responsibility or liability arising out of the application or use of any information, product, or service described herein except as expressly agreed to in writing by Altera Corporation. Altera customers are advised to obtain the latest version of device specifications before relying on any published information and before placing orders for products or services. Altera Corporation