source: firmware/FTM/test_firmware/FTM_test2/FTM_test2_backup.vhd@ 17370

Last change on this file since 17370 was 10046, checked in by vogler, 14 years ago
Test firmware for FTM hardware testing
  • Property svn:executable set to *
File size: 16.9 KB
Line 
1----------------------------------------------------------------------------------
2-- Company: ETH Zurich, Institute for Particle Physics
3-- Engineer: P. Vogler, Q. Weitzel
4--
5-- Create Date: 13 October 2010
6-- Design Name:
7-- Module Name: FTU_test2 - Behavioral
8-- Project Name:
9-- Target Devices:
10-- Tool versions:
11-- Description: Test firmware for FTM board:
12-- NIM and LVDS output stages
13-- fast signal distribution (partially)
14-- crate resets
15--
16--
17--
18-- Dependencies:
19--
20-- Revision:
21-- Revision 0.01 - File Created
22-- Additional Comments:
23--
24----------------------------------------------------------------------------------
25
26library IEEE;
27use IEEE.STD_LOGIC_1164.ALL;
28use IEEE.STD_LOGIC_ARITH.ALL;
29use IEEE.STD_LOGIC_UNSIGNED.ALL;
30
31---- Uncomment the following library declaration if instantiating
32---- any Xilinx primitives in this code.
33library UNISIM;
34use UNISIM.VComponents.all;
35
36entity FTM_test2 is
37 port(
38
39
40-- Clock
41 clk : IN STD_LOGIC; -- external clock from
42 -- oscillator U47
43
44-- connection to the WIZnet W5300 ethernet controller
45-- on IO-Bank 1
46-------------------------------------------------------------------------------
47 -- W5300 data bus
48-- W_D : inout STD_LOGIC_VECTOR(15 downto 0); -- 16-bit data bus to W5300
49
50
51 -- W5300 address bus
52-- W_A : out STD_LOGIC_VECTOR(9 downto 1); -- there is NO net W_A0 because
53 -- the W5300 is operated in the
54 -- 16-bit mode
55
56 -- W5300 controll signals
57 -- the signals W_INT, W_RD, W_WR and W_RES also go to testpoints T17
58 -- W_CS is also routed to testpoint JP7
59-- W_CS : out STD_LOGIC; -- W5300 chip select
60-- W_INT : IN STD_LOGIC; -- interrupt
61-- W_RD : out STD_LOGIC; -- read
62-- W_WR : out STD_LOGIC; -- write
63-- W_RES : out STD_LOGIC; -- reset W5300 chip
64
65 -- W5300 buffer ready indicator
66-- W_BRDY : in STD_LOGIC_VECTOR(3 downto 0);
67
68 -- testpoints (T18) associated with the W5300 on IO-bank 1
69-- W_T : inout STD_LOGIC_VECTOR(3 downto 0);
70
71
72
73-- SPI Interface
74-- connection to the EEPROM U36 (AL25L016M) and
75-- temperature sensors U45, U46, U48 and U49 (all MAX6662)
76-- on IO-Bank 1
77-------------------------------------------------------------------------------
78-- S_CLK : out STD_LOGIC; -- SPI clock
79
80 -- EEPROM
81-- MOSI : out STD_LOGIC; -- master out slave in
82-- MISO : in STD_LOGIC; -- master in slave out
83-- EE_CS : out STD_LOGIC; -- EEPROM chip select
84
85 -- temperature sensors U45, U46, U48 and U49
86-- SIO : inout STD_LOGIC; -- serial IO
87-- TS_CS : out STD_LOGIC_VECTOR(3 downto 0); -- temperature sensors chip select
88
89
90
91-- Trigger primitives inputs
92-- on IO-Bank 2
93-------------------------------------------------------------------------------
94-- Trig_Prim_A : in STD_LOGIC_VECTOR(9 downto 0); -- crate 0
95-- Trig_Prim_B : in STD_LOGIC_VECTOR(9 downto 0); -- crate 1
96-- Trig_Prim_C : in STD_LOGIC_VECTOR(9 downto 0); -- crate 2
97-- Trig_Prim_D : in STD_LOGIC_VECTOR(9 downto 0); -- crate 3
98
99
100
101-- NIM inputs
102------------------------------------------------------------------------------
103 -- on IO-Bank 3
104-- ext_Trig : in STD_LOGIC_VECTOR(2 downto 1); -- external trigger input
105-- Veto : in STD_LOGIC; -- trigger veto input
106-- NIM_In : in STD_LOGIC_VECTOR(2 downto 0); -- auxiliary inputs
107
108 -- on IO-Bank 0
109-- NIM_In3_GCLK : in STD_LOGIC; -- input with global clock buffer available
110
111
112
113-- LEDs on IO-Banks 0 and 3
114-------------------------------------------------------------------------------
115-- LED_red : out STD_LOGIC_VECTOR(3 downto 0); -- red
116-- LED_ye : out STD_LOGIC_VECTOR(1 downto 0); -- yellow
117-- LED_gn : out STD_LOGIC_VECTOR(1 downto 0); -- green
118
119
120
121-- Clock conditioner LMK03000
122-- on IO-Bank 3
123-------------------------------------------------------------------------------
124-- CLK_Clk_Cond : out STD_LOGIC; -- clock conditioner MICROWIRE interface clock
125-- LE_Clk_Cond : out STD_LOGIC; -- clock conditioner MICROWIRE interface latch enable
126-- DATA_Clk_Cond : out STD_LOGIC; -- clock conditioner MICROWIRE interface data
127
128-- SYNC_Clk_Cond : out STD_LOGIC; -- clock conditioner global clock synchronization
129-- LD_Clk_Cond : in STD_LOGIC; -- clock conditioner lock detect
130
131
132
133
134-- various RS-485 Interfaces
135-- on IO-Bank 3
136-------------------------------------------------------------------------------
137 -- Bus 1: FTU slow control
138-- Bus1_Tx_En : out STD_LOGIC; -- bus 1: transmitter enable
139-- Bus1_Rx_En : out STD_LOGIC; -- bus 1: receiver enable
140
141-- Bus1_RxD_0 : in STD_LOGIC; -- crate 0
142-- Bus1_TxD_0 : out STD_LOGIC;
143
144-- Bus1_RxD_1 : in STD_LOGIC; -- crate 1
145-- Bus1_TxD_1 : out STD_LOGIC;
146
147-- Bus1_RxD_2 : in STD_LOGIC; -- crate 2
148-- Bus1_TxD_2 : out STD_LOGIC;
149
150-- Bus1_RxD_3 : in STD_LOGIC; -- crate 3
151-- Bus1_TxD_3 : out STD_LOGIC;
152
153
154 -- Bus 2: Trigger-ID to FAD boards
155-- Bus2_Tx_En : out STD_LOGIC; -- bus 2: transmitter enable
156-- Bus2_Rx_En : out STD_LOGIC; -- bus 2: receiver enable
157
158-- Bus2_RxD_0 : in STD_LOGIC; -- crate 0
159-- Bus2_TxD_0 : out STD_LOGIC;
160
161-- Bus2_RxD_1 : in STD_LOGIC; -- crate 1
162-- Bus2_TxD_1 : out STD_LOGIC;
163
164-- Bus2_RxD_2 : in STD_LOGIC; -- crate 2
165-- Bus2_TxD_2 : out STD_LOGIC;
166
167-- Bus2_RxD_3 : in STD_LOGIC; -- crate 3
168-- Bus2_TxD_3 : out STD_LOGIC;
169
170
171-- auxiliary access
172-- Aux_Rx_D : in STD_LOGIC; --
173-- Aux_Tx_D : out STD_LOGIC; --
174-- Aux_Rx_En : out STD_LOGIC; -- Rx- and Tx enable
175-- Aux_Tx_En : out STD_LOGIC; -- also for auxiliary Trigger-ID
176
177
178-- auxiliary Trigger-ID (i.e. to send the Trigger-ID to the counting hut/house/container)
179-- TrID_Rx_D : in STD_LOGIC; --
180-- TrID_Tx_D : out STD_LOGIC; --
181
182
183-- Crate-Resets
184-- on IO-Bank 3
185-------------------------------------------------------------------------------
186 Crate_Res0 : out STD_LOGIC; --
187 Crate_Res1 : out STD_LOGIC; --
188 Crate_Res2 : out STD_LOGIC; --
189 Crate_Res3 : out STD_LOGIC; --
190
191
192-- Busy signals from the FAD boards
193-- on IO-Bank 3
194-------------------------------------------------------------------------------
195-- Busy0 : in STD_LOGIC; --
196-- Busy1 : in STD_LOGIC; --
197-- Busy2 : in STD_LOGIC; --
198-- Busy3 : in STD_LOGIC; --
199
200
201
202-- NIM outputs
203-- on IO-Bank 0
204-- LVDS output at the FPGA followed by LVDS to NIM conversion stage
205-------------------------------------------------------------------------------
206-- calibration
207 Cal_NIM1_p : out STD_LOGIC; -- Cal_NIM1+
208 Cal_NIM1_n : out STD_LOGIC; -- Cal_NIM1-
209 Cal_NIM2_p : out STD_LOGIC; -- Cal_NIM2+
210 Cal_NIM2_n : out STD_LOGIC; -- Cal_NIM2-
211
212-- auxiliarry / spare NIM outputs
213 NIM_Out0_p : out STD_LOGIC; -- NIM_Out0+
214 NIM_Out0_n : out STD_LOGIC; -- NIM_Out0-
215 NIM_Out1_p : out STD_LOGIC; -- NIM_Out1+
216 NIM_Out1_n : out STD_LOGIC; -- NIM_Out1-
217
218
219
220-- fast control signal outputs
221-- LVDS output at the FPGA followed by LVDS to NIM conversion stage
222-- conversion stage
223-------------------------------------------------------------------------------
224 RES_p : out STD_LOGIC; -- RES+ Reset
225 RES_n : out STD_LOGIC; -- RES- IO-Bank 0
226
227 TRG_p : out STD_LOGIC; -- TRG+ Trigger
228 TRG_n : out STD_LOGIC; -- TRG- IO-Bank 0
229
230 TIM_Run_p : out STD_LOGIC; -- TIM_Run+ Time Marker
231 TIM_Run_n : out STD_LOGIC; -- TIM_Run- IO-Bank 2
232 TIM_Sel : out STD_LOGIC; -- Time Marker selector on
233 -- IO-Bank 2
234
235-- CLD_FPGA : out STD_LOGIC; -- DRS-Clock feedback into FPGA
236
237
238
239-- LVDS calibration outputs
240-- on IO-Bank 0
241-------------------------------------------------------------------------------
242-- to connector J13
243 Cal_0_p : out STD_LOGIC;
244 Cal_0_n : out STD_LOGIC;
245 Cal_1_p : out STD_LOGIC;
246 Cal_1_n : out STD_LOGIC;
247 Cal_2_p : out STD_LOGIC;
248 Cal_2_n : out STD_LOGIC;
249 Cal_3_p : out STD_LOGIC;
250 Cal_3_n : out STD_LOGIC;
251
252-- to connector J12
253 Cal_4_p : out STD_LOGIC;
254 Cal_4_n : out STD_LOGIC;
255 Cal_5_p : out STD_LOGIC;
256 Cal_5_n : out STD_LOGIC;
257 Cal_6_p : out STD_LOGIC;
258 Cal_6_n : out STD_LOGIC;
259 Cal_7_p : out STD_LOGIC;
260 Cal_7_n : out STD_LOGIC
261
262
263-- Testpoints
264-------------------------------------------------------------------------------
265-- TP : inout STD_LOGIC_VECTOR(32 downto 0)
266-- TP_in : in STD_LOGIC_VECTOR(34 downto 33); -- input only
267
268-- Board ID - inputs
269-- local board-ID "solder programmable"
270-- all on 'input only' pins
271-------------------------------------------------------------------------------
272-- brd_id : in STD_LOGIC_VECTOR(7 downto 0) -- input only
273 );
274end FTM_test2;
275
276
277
278
279
280architecture Behavioral of FTM_test2 is
281
282 component FTM_test2_dcm
283 port ( CLKIN_IN : in std_logic;
284 CLKFX_OUT : out std_logic;
285 CLKIN_IBUFG_OUT : out std_logic);
286 end component;
287
288 component Clock_Divider
289 port(
290 clock : IN STD_LOGIC;
291 enable_out : OUT STD_LOGIC
292 );
293 end component;
294
295 component Clock_Divider_2
296 port(
297 clock : IN STD_LOGIC;
298 enable_out_2 : OUT STD_LOGIC
299 );
300 end component;
301
302
303 signal clk_200M_sig : STD_LOGIC;
304 signal enable_sig : STD_LOGIC;
305 signal enable_sig2 : STD_LOGIC;
306
307
308begin
309
310
311
312
313
314
315
316 OBUFDS_inst_TRG : OBUFDS
317 generic map (
318 IOSTANDARD => "DEFAULT")
319 port map (
320 O => TRG_p, -- Diff_p output (connect directly to top-level port)
321 OB => TRG_n, -- Diff_n output (connect directly to top-level port)
322 I => enable_sig2 -- Buffer input
323 );
324
325
326
327 OBUFDS_inst_RES : OBUFDS
328 generic map (
329 IOSTANDARD => "DEFAULT")
330 port map (
331 O => RES_p, -- Diff_p output (connect directly to top-level port)
332 OB => RES_n, -- Diff_n output (connect directly to top-level port)
333 I => enable_sig2 -- Buffer input
334 );
335
336
337
338 OBUFDS_inst_TIM : OBUFDS
339 generic map (
340 IOSTANDARD => "DEFAULT")
341 port map (
342 O => TIM_Run_p, -- Diff_p output (connect directly to top-level port)
343 OB => TIM_Run_n, -- Diff_n output (connect directly to top-level port)
344 I => enable_sig2 -- Buffer input
345 );
346
347 TIM_Sel <= '0';
348
349 Crate_Res0 <= enable_sig;
350 Crate_Res1 <= enable_sig;
351 Crate_Res2 <= enable_sig;
352 Crate_Res3 <= enable_sig;
353
354
355
356
357
358 OBUFDS_inst_Cal_NIM1 : OBUFDS
359 generic map (
360 IOSTANDARD => "DEFAULT")
361 port map (
362 O => Cal_NIM1_p, -- Diff_p output (connect directly to top-level port)
363 OB => Cal_NIM1_n, -- Diff_n output (connect directly to top-level port)
364 I => enable_sig2 -- Buffer input
365 );
366
367
368 OBUFDS_inst_Cal_NIM2 : OBUFDS
369 generic map (
370 IOSTANDARD => "DEFAULT")
371 port map (
372 O => Cal_NIM2_p, -- Diff_p output (connect directly to top-level port)
373 OB => Cal_NIM2_n, -- Diff_n output (connect directly to top-level port)
374 I => not enable_sig2 -- Buffer input
375 );
376
377
378
379
380 OBUFDS_inst_NIM_Out0 : OBUFDS
381 generic map (
382 IOSTANDARD => "DEFAULT")
383 port map (
384 O => NIM_Out0_p, -- Diff_p output (connect directly to top-level port)
385 OB => NIM_Out0_n, -- Diff_n output (connect directly to top-level port)
386 I => enable_sig2 -- Buffer input
387 );
388
389
390 OBUFDS_inst_NIM_Out1 : OBUFDS
391 generic map (
392 IOSTANDARD => "DEFAULT")
393 port map ( O => NIM_Out1_p, -- Diff_p output (connect directly to top-level port)
394 OB => NIM_Out1_n, -- Diff_n output (connect directly to top-level port)
395 I => enable_sig2 -- Buffer input
396 );
397
398
399
400
401
402 OBUFDS_inst_Cal_0 : OBUFDS
403 generic map (
404 IOSTANDARD => "DEFAULT")
405 port map ( O => Cal_0_p , -- Diff_p output (connect directly to top-level port)
406 OB => Cal_0_n , -- Diff_n output (connect directly to top-level port)
407 I => enable_sig2 -- Buffer input
408 );
409
410 OBUFDS_inst_Cal_1 : OBUFDS
411 generic map (
412 IOSTANDARD => "DEFAULT")
413 port map ( O => Cal_1_p , -- Diff_p output (connect directly to top-level port)
414 OB => Cal_1_n , -- Diff_n output (connect directly to top-level port)
415 I => enable_sig2 -- Buffer input
416 );
417
418 OBUFDS_inst_Cal_2 : OBUFDS
419 generic map (
420 IOSTANDARD => "DEFAULT")
421 port map ( O => Cal_2_p , -- Diff_p output (connect directly to top-level port)
422 OB => Cal_2_n , -- Diff_n output (connect directly to top-level port)
423 I => enable_sig2 -- Buffer input
424 );
425
426 OBUFDS_inst_Cal_3 : OBUFDS
427 generic map (
428 IOSTANDARD => "DEFAULT")
429 port map ( O => Cal_3_p , -- Diff_p output (connect directly to top-level port)
430 OB => Cal_3_n , -- Diff_n output (connect directly to top-level port)
431 I => enable_sig2 -- Buffer input
432 );
433
434 OBUFDS_inst_Cal_4 : OBUFDS
435 generic map (
436 IOSTANDARD => "DEFAULT")
437 port map ( O => Cal_4_p , -- Diff_p output (connect directly to top-level port)
438 OB => Cal_4_n , -- Diff_n output (connect directly to top-level port)
439 I => enable_sig2 -- Buffer input
440 );
441
442 OBUFDS_inst_Cal_5 : OBUFDS
443 generic map (
444 IOSTANDARD => "DEFAULT")
445 port map ( O => Cal_5_p , -- Diff_p output (connect directly to top-level port)
446 OB => Cal_5_n , -- Diff_n output (connect directly to top-level port)
447 I => enable_sig2 -- Buffer input
448 );
449
450 OBUFDS_inst_Cal_6 : OBUFDS
451 generic map (
452 IOSTANDARD => "DEFAULT")
453 port map ( O => Cal_6_p , -- Diff_p output (connect directly to top-level port)
454 OB => Cal_6_n , -- Diff_n output (connect directly to top-level port)
455 I => enable_sig2 -- Buffer input
456 );
457
458 OBUFDS_inst_Cal_7 : OBUFDS
459 generic map (
460 IOSTANDARD => "DEFAULT")
461 port map ( O => Cal_7_p , -- Diff_p output (connect directly to top-level port)
462 OB => Cal_7_n , -- Diff_n output (connect directly to top-level port)
463 I => enable_sig2 -- Buffer input
464 );
465
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479
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481
482 Inst_FTU_test2_dcm : FTM_test2_dcm
483 port map(
484 CLKIN_IN => clk,
485 CLKFX_OUT => clk_200M_sig,
486 CLKIN_IBUFG_OUT => open
487 );
488
489
490 Inst_Clock_Divider : Clock_Divider
491 port map (
492 clock => clk_200M_sig,
493 enable_out => enable_sig
494 );
495
496
497 Inst_Clock_Divider_2 : Clock_Divider_2
498 port map (
499 clock => clk_200M_sig,
500 enable_out_2 => enable_sig2
501 );
502
503
504
505
506end Behavioral;
507
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535
536library IEEE;
537use IEEE.STD_LOGIC_1164.ALL;
538use IEEE.STD_LOGIC_ARITH.ALL;
539use IEEE.STD_LOGIC_UNSIGNED.ALL;
540
541entity Clock_Divider is
542 port(
543 clock : in std_logic;
544 enable_out: out std_logic
545 );
546end entity Clock_Divider;
547
548architecture RTL of Clock_Divider is
549
550 --constant max_count : integer := 5000000/1000000; -- for simulation
551 constant max_count : integer := 250000/1; -- for implementation
552-- constant final_count : integer := 100;
553
554begin
555
556 process(clock)
557 variable count : integer range 0 to max_count;
558-- variable count2 : integer range 0 to final_count;
559 begin
560 if rising_edge(clock) then
561 --enable_out <= '0';
562-- if count2 = final_count then
563-- enable_out <= '0';
564-- else
565 if count < max_count/2 then
566 enable_out <= '0';
567 count := count + 1;
568 elsif count < max_count then
569 enable_out <= '1';
570 count := count + 1;
571 else
572 count := 0;
573 enable_out <= '0';
574-- count2 := count2 + 1;
575 end if;
576-- end if;
577 end if;
578 end process;
579
580end architecture RTL;
581
582
583
584
585
586entity Clock_Divider_2 is
587 port(
588 clock : in std_logic;
589 enable_out_2 : out std_logic
590 );
591end entity Clock_Divider_2;
592
593architecture RTL of Clock_Divider_2 is
594
595constant max_count_2 : integer := 200/1; -- for implementation
596
597begin
598
599 process(clock)
600 variable count_2 : integer range 0 to max_count_2;
601
602 begin
603 if rising_edge(clock) then
604 if count_2 < max_count_2/2 then
605 enable_out_2 <= '0';
606 count_2 := count + 1;
607 elsif count_2 < max_count then
608 enable_out_2 <= '1';
609 count_2 := count_2 + 1;
610 else
611 count_2 := 0;
612 enable_out_2 <= '0';
613 end if;
614 end if;
615 end process;
616
617end architecture RTL;
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