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|
// --------------------------------------------------------------------
// Copyright (c) 2007 by Terasic Technologies Inc.
// --------------------------------------------------------------------
//
// Permission:
//
// Terasic grants permission to use and modify this code for use
// in synthesis for all Terasic Development Boards and Altera Development
// Kits made by Terasic. Other use of this code, including the selling
// ,duplication, or modification of any portion is strictly prohibited.
//
// Disclaimer:
//
// This VHDL/Verilog or C/C++ source code is intended as a design reference
// which illustrates how these types of functions can be implemented.
// It is the user's responsibility to verify their design for
// consistency and functionality through the use of formal
// verification methods. Terasic provides no warranty regarding the use
// or functionality of this code.
//
// --------------------------------------------------------------------
//
// Terasic Technologies Inc
// 356 Fu-Shin E. Rd Sec. 1. JhuBei City,
// HsinChu County, Taiwan
// 302
//
// web: http://www.terasic.com/
// email: support@terasic.com
//
// --------------------------------------------------------------------
//
// Major Functions: DE0_D5M
//
// --------------------------------------------------------------------
//
// Revision History :
// --------------------------------------------------------------------
// Ver :| Author :| Mod. Date :| Changes Made:
// V1.0 :| Johnny FAN :| 07/07/09 :| Initial Revision
// V2.0 :| Rui Duarte :| 12/03/14 :| DE0 support
// --------------------------------------------------------------------
module DE0_D5M
(
//////////////////// Clock Input ////////////////////
CLOCK_50, // 50 MHz
//////////////////// Push Button ////////////////////
KEY, // Pushbutton[2:0]
//////////////////// DPDT Switch ////////////////////
SW, // Toggle Switch[9:0]
//////////////////////// LED ////////////////////////
LEDG, // LED Green[9:0]
//////////////////// 7-SEG Dispaly ////////////////////
HEX0, // Seven Segment Digit 0
HEX1, // Seven Segment Digit 1
HEX2, // Seven Segment Digit 2
HEX3, // Seven Segment Digit 3
///////////////////// SDRAM Interface ////////////////
DRAM_DQ, // SDRAM Data bus 16 Bits
DRAM_ADDR, // SDRAM Address bus 12 Bits
DRAM_LDQM, // SDRAM Low-byte Data Mask
DRAM_UDQM, // SDRAM High-byte Data Mask
DRAM_WE_N, // SDRAM Write Enable
DRAM_CAS_N, // SDRAM Column Address Strobe
DRAM_RAS_N, // SDRAM Row Address Strobe
DRAM_CS_N, // SDRAM Chip Select
DRAM_BA_0, // SDRAM Bank Address 0
DRAM_BA_1, // SDRAM Bank Address 0
DRAM_CLK, // SDRAM Clock
DRAM_CKE, // SDRAM Clock Enable
//////////////////// VGA ////////////////////////////
VGA_HS, // VGA H_SYNC
VGA_VS, // VGA V_SYNC
VGA_R, // VGA Red[3:0]
VGA_G, // VGA Green[3:0]
VGA_B, // VGA Blue[3:0]
VGA_CLK, // VGA Clk
VGA_X, // VGA X scan coord
VGA_Y, // VGA Y scan coord
VGA_ACTIVE, // VGA ACTIVE
//////////////////// GPIO ////////////////////////////
//GPIO_0, // GPIO Connection 0
GPIO_1_CLKIN, // GPIO Connection 1 CLK INPUTS
GPIO_1_CLKOUT, // GPIO Connection 1 CLK OUTPUTS
GPIO_1 // GPIO Connection 1
);
//////////////////////// Clock Input ////////////////////////
input CLOCK_50; // 50 MHz
//////////////////////// Push Button ////////////////////////
input [2:0] KEY; // Pushbutton[3:0]
//////////////////////// DPDT Switch ////////////////////////
input [9:0] SW; // Toggle Switch[9:0]
//////////////////////////// LED ////////////////////////////
output [9:0] LEDG; // LED Green[7:0]
//////////////////////// 7-SEG Dispaly ////////////////////////
output [6:0] HEX0; // Seven Segment Digit 0
output [6:0] HEX1; // Seven Segment Digit 1
output [6:0] HEX2; // Seven Segment Digit 2
output [6:0] HEX3; // Seven Segment Digit 3
/////////////////////// SDRAM Interface ////////////////////////
inout [15:0] DRAM_DQ; // SDRAM Data bus 16 Bits
output[11:0] DRAM_ADDR; // SDRAM Address bus 12 Bits
output DRAM_LDQM; // SDRAM Low-byte Data Mask
output DRAM_UDQM; // SDRAM High-byte Data Mask
output DRAM_WE_N; // SDRAM Write Enable
output DRAM_CAS_N; // SDRAM Column Address Strobe
output DRAM_RAS_N; // SDRAM Row Address Strobe
output DRAM_CS_N; // SDRAM Chip Select
output DRAM_BA_0; // SDRAM Bank Address 0
output DRAM_BA_1; // SDRAM Bank Address 0
output DRAM_CLK; // SDRAM Clock
output DRAM_CKE; // SDRAM Clock Enable
//////////////////////// VGA ////////////////////////////
output VGA_HS; // VGA H_SYNC
output VGA_VS; // VGA V_SYNC
output [3:0] VGA_R; // VGA Red[3:0]
output [3:0] VGA_G; // VGA Green[3:0]
output [3:0] VGA_B; // VGA Blue[3:0]
output VGA_CLK; // VGA Clk
output [11:0] VGA_X; // VGA X scan coord
output [11:0] VGA_Y; // VGA Y scan coord
output VGA_ACTIVE; // VGA ACTIVE
//////////////////////// GPIO ////////////////////////////////
input [1:0] GPIO_1_CLKIN; // GPIO Connection 1 - need stand alone inputs for external clock, pins on the board rewired
output [1:0] GPIO_1_CLKOUT; // GPIO Connection 1 - need stand alone outputs for external clock, pins on the board rewired
inout [31:0] GPIO_1; // GPIO Connection 1
///////////////////////////////////////////////////////////////////
//=============================================================================
// REG/WIRE declarations
//=============================================================================
// CCD
wire [11:0] CCD_DATA;
wire CCD_SDAT;
wire CCD_SCLK;
wire CCD_FLASH;
wire CCD_FVAL;
wire CCD_LVAL;
wire CCD_PIXCLK;
wire CCD_MCLK; // CCD Master Clock
wire [15:0] Read_DATA1;
wire [15:0] Read_DATA2;
wire VGA_CTRL_CLK;
wire [11:0] mCCD_DATA;
wire mCCD_DVAL;
wire mCCD_DVAL_d;
wire [15:0] X_Cont;
wire [15:0] Y_Cont;
wire [9:0] X_ADDR;
wire [31:0] Frame_Cont;
wire DLY_RST_0;
wire DLY_RST_1;
wire DLY_RST_2;
wire Read;
reg [11:0] rCCD_DATA;
reg rCCD_LVAL;
reg rCCD_FVAL;
wire [11:0] sCCD_R;
wire [11:0] sCCD_G;
wire [11:0] sCCD_B;
wire sCCD_DVAL;
wire [9:0] VGA_R; // VGA Red[9:0]
wire [9:0] VGA_G; // VGA Green[9:0]
wire [9:0] VGA_B; // VGA Blue[9:0]
wire [11:0] VGA_X; // VGA X scan
wire [11:0] VGA_Y; // VGA Y scan
wire VGA_ACTIVE;
reg [1:0] rClk;
wire sdram_ctrl_clk;
//=============================================================================
// Structural coding
//=============================================================================
assign CCD_DATA[0] = GPIO_1[11];
assign CCD_DATA[1] = GPIO_1[10];
assign CCD_DATA[2] = GPIO_1[9];
assign CCD_DATA[3] = GPIO_1[8];
assign CCD_DATA[4] = GPIO_1[7];
assign CCD_DATA[5] = GPIO_1[6];
assign CCD_DATA[6] = GPIO_1[5];
assign CCD_DATA[7] = GPIO_1[4];
assign CCD_DATA[8] = GPIO_1[3];
assign CCD_DATA[9] = GPIO_1[2];
assign CCD_DATA[10]= GPIO_1[1];
assign CCD_DATA[11]= GPIO_1[0];
assign GPIO_1_CLKOUT[0] = CCD_MCLK;
assign CCD_FVAL = GPIO_1[18];
assign CCD_LVAL = GPIO_1[17];
assign CCD_PIXCLK = GPIO_1_CLKIN[0];
assign GPIO_1[15] = 1'b1; // tRIGGER
assign GPIO_1[14] = DLY_RST_1;
assign LEDG = Y_Cont;
assign VGA_CTRL_CLK= rClk[0];
assign VGA_CLK = ~rClk[0];
always@(posedge CLOCK_50) rClk <= rClk+1;
wire [9:0] oVGA_R;
wire [9:0] oVGA_G;
wire [9:0] oVGA_B;
assign VGA_R = oVGA_R[9:0];
assign VGA_G = oVGA_G[9:0];
assign VGA_B = oVGA_B[9:0];
// vga scan coordinates
wire [11:0] oVGA_X;
wire [11:0] oVGA_Y;
assign VGA_X = oVGA_Y;
assign VGA_Y = oVGA_X;
// vga output active
wire oVGA_ACTIVE;
assign VGA_ACTIVE = oVGA_ACTIVE;
always@(posedge CCD_PIXCLK)
begin
rCCD_DATA <= CCD_DATA;
rCCD_LVAL <= CCD_LVAL;
rCCD_FVAL <= CCD_FVAL;
end
VGA_Controller u1 ( // Host Side
.oRequest (Read),
// .iRed (10'b1111111111),
// .iGreen (10'b0000000000),
// .iBlue (10'b0000000000),
.iRed (Read_DATA2[9:0]),
.iGreen ({Read_DATA1[14:10],Read_DATA2[14:10]}),
.iBlue (Read_DATA1[9:0]),
// VGA Side
.oVGA_R (oVGA_R),
.oVGA_G (oVGA_G),
.oVGA_B (oVGA_B),
.oVGA_H_SYNC(VGA_HS),
.oVGA_V_SYNC(VGA_VS),
// VGA Scan Coordinates
.oVGA_X(oVGA_X),
.oVGA_Y(oVGA_Y),
.oVGA_ACTIVE(oVGA_ACTIVE),
// Control Signal
.iCLK (VGA_CTRL_CLK),
.iRST_N (DLY_RST_2)
);
Reset_Delay u2 (
.iCLK (CLOCK_50),
.iRST (KEY[0]),
.oRST_0(DLY_RST_0),
.oRST_1(DLY_RST_1),
.oRST_2(DLY_RST_2)
);
CCD_Capture u3 (
.oDATA (mCCD_DATA),
.oDVAL (mCCD_DVAL),
.oX_Cont (X_Cont),
.oY_Cont (Y_Cont),
.oFrame_Cont(Frame_Cont),
.iDATA (rCCD_DATA),
.iFVAL (rCCD_FVAL),
.iLVAL (rCCD_LVAL),
.iSTART (!KEY[1]),
.iEND (!KEY[2]),
.iCLK (CCD_PIXCLK),
.iRST (DLY_RST_2)
);
RAW2RGB u4 (
.iCLK (CCD_PIXCLK),
.iRST (DLY_RST_1),
.iDATA (mCCD_DATA),
.iDVAL (mCCD_DVAL),
.oRed (sCCD_R),
.oGreen (sCCD_G),
.oBlue (sCCD_B),
.oDVAL (sCCD_DVAL),
.iX_Cont(X_Cont),
.iY_Cont(Y_Cont)
);
SEG7_LUT_8 u5 (
.oSEG0(HEX0),
.oSEG1(HEX1),
.oSEG2(HEX2),
.oSEG3(HEX3),
.oSEG4(),
.oSEG5(),
.oSEG6(),
.oSEG7(),
.iDIG (Frame_Cont[31:0])
);
sdram_pll u6 (
.inclk0(CLOCK_50),
.c0 (sdram_ctrl_clk),
.c1 (DRAM_CLK)
);
assign CCD_MCLK = rClk[0];
Sdram_Control_4Port u7 ( // HOST Side
.REF_CLK (CLOCK_50),
.RESET_N (1'b1),
.CLK (sdram_ctrl_clk),
// FIFO Write Side 1
.WR1_DATA ({1'b0,sCCD_G[11:7],sCCD_B[11:2]}),
.WR1 (sCCD_DVAL),
.WR1_ADDR (0),
.WR1_MAX_ADDR(640*480),
.WR1_LENGTH (9'h100),
.WR1_LOAD (!DLY_RST_0),
.WR1_CLK (~CCD_PIXCLK),
// FIFO Write Side 2
.WR2_DATA ({1'b0,sCCD_G[6:2],sCCD_R[11:2]}),
.WR2 (sCCD_DVAL),
.WR2_ADDR (22'h100000),
.WR2_MAX_ADDR(22'h100000+640*480),
.WR2_LENGTH (9'h100),
.WR2_LOAD (!DLY_RST_0),
.WR2_CLK (~CCD_PIXCLK),
// FIFO Read Side 1
.RD1_DATA (Read_DATA1),
.RD1 (Read),
.RD1_ADDR (0),
.RD1_MAX_ADDR(640*480),
.RD1_LENGTH (9'h100),
.RD1_LOAD (!DLY_RST_0),
.RD1_CLK (~VGA_CTRL_CLK),
// FIFO Read Side 2
.RD2_DATA (Read_DATA2),
.RD2 (Read),
.RD2_ADDR (22'h100000),
.RD2_MAX_ADDR(22'h100000+640*480),
.RD2_LENGTH (9'h100),
.RD2_LOAD (!DLY_RST_0),
.RD2_CLK (~VGA_CTRL_CLK),
// SDRAM Side
.SA (DRAM_ADDR),
.BA ({DRAM_BA_1,DRAM_BA_0}),
.CS_N (DRAM_CS_N),
.CKE (DRAM_CKE),
.RAS_N (DRAM_RAS_N),
.CAS_N (DRAM_CAS_N),
.WE_N (DRAM_WE_N),
.DQ (DRAM_DQ),
.DQM ({DRAM_UDQM,DRAM_LDQM})
);
I2C_CCD_Config u8 ( // Host Side
.iCLK (CLOCK_50),
.iRST_N (DLY_RST_2),
.iZOOM_MODE_SW (SW[2]),
.iEXPOSURE_ADJ (SW[1]),
.iEXPOSURE_DEC_p(SW[0]),
// I2C Side
.I2C_SCLK (GPIO_1[20]),
.I2C_SDAT (GPIO_1[19])
);
endmodule
|