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FTM_test9.vhd@ 12379

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Last change on this file since 12379 was 10104, checked in by weitzel, 14 years ago
FTM_test9 added: check FTM-FTU communication
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 January 2011
6	-- Design Name:
7	-- Module Name: FTM_test9 - Behavioral
8	-- Project Name:
9	-- Target Devices:
10	-- Tool versions:
11	-- Description: Test firmware for FTM board: try to contact FTU via RS485
12	--
13	--
14	-- Dependencies:
15	--
16	-- Revision:
17	-- Revision 0.01 - File Created
18	-- Additional Comments:
19	--
20	----------------------------------------------------------------------------------
21
22	library IEEE;
23	use IEEE.STD_LOGIC_1164.ALL;
24	use IEEE.STD_LOGIC_ARITH.ALL;
25	use IEEE.STD_LOGIC_UNSIGNED.ALL;
26
27	---- Uncomment the following library declaration if instantiating
28	---- any Xilinx primitives in this code.
29	library UNISIM;
30	use UNISIM.VComponents.all;
31
32	entity FTM_test9 is
33	port(
34
35	-- Clock
36	clk : IN STD_LOGIC; -- external clock from
37	-- oscillator U47
38	-- connection to the WIZnet W5300 ethernet controller
39	-- on IO-Bank 1
40	-------------------------------------------------------------------------------
41	-- W5300 data bus
42	-- W_D : inout STD_LOGIC_VECTOR(15 downto 0); -- 16-bit data bus to W5300
43
44
45	-- W5300 address bus
46	-- W_A : out STD_LOGIC_VECTOR(9 downto 1); -- there is NO net W_A0 because
47	-- the W5300 is operated in the
48	-- 16-bit mode
49
50	-- W5300 controll signals
51	-- the signals W_INT, W_RD, W_WR and W_RES also go to testpoints T17
52	-- W_CS is also routed to testpoint JP7
53	-- W_CS : out STD_LOGIC; -- W5300 chip select
54	-- W_INT : IN STD_LOGIC; -- interrupt
55	-- W_RD : out STD_LOGIC; -- read
56	-- W_WR : out STD_LOGIC; -- write
57	-- W_RES : out STD_LOGIC -- reset W5300 chip
58
59	-- W5300 buffer ready indicator
60	-- W_BRDY : in STD_LOGIC_VECTOR(3 downto 0);
61
62	-- testpoints (T18) associated with the W5300 on IO-bank 1
63	-- W_T : inout STD_LOGIC_VECTOR(3 downto 0);
64
65
66
67	-- SPI Interface
68	-- connection to the EEPROM U36 (AL25L016M) and
69	-- temperature sensors U45, U46, U48 and U49 (all MAX6662)
70	-- on IO-Bank 1
71	-------------------------------------------------------------------------------
72	-- S_CLK : out STD_LOGIC; -- SPI clock
73
74	-- EEPROM
75	-- MOSI : out STD_LOGIC; -- master out slave in
76	-- MISO : in STD_LOGIC; -- master in slave out
77	-- EE_CS : out STD_LOGIC; -- EEPROM chip select
78
79	-- temperature sensors U45, U46, U48 and U49
80	-- SIO : inout STD_LOGIC; -- serial IO
81	-- TS_CS : out STD_LOGIC_VECTOR(3 downto 0); -- temperature sensors chip select
82
83
84
85	-- Trigger primitives inputs
86	-- on IO-Bank 2
87	-------------------------------------------------------------------------------
88	-- Trig_Prim_A : in STD_LOGIC_VECTOR(9 downto 0); -- crate 0
89	-- Trig_Prim_B : in STD_LOGIC_VECTOR(9 downto 0); -- crate 1
90	-- Trig_Prim_C : in STD_LOGIC_VECTOR(9 downto 0); -- crate 2
91	-- Trig_Prim_D : in STD_LOGIC_VECTOR(9 downto 0); -- crate 3
92
93
94
95	-- NIM inputs
96	------------------------------------------------------------------------------
97	-- on IO-Bank 3
98	-- ext_Trig : in STD_LOGIC_VECTOR(2 downto 1); -- external trigger input
99	-- Veto : in STD_LOGIC; -- trigger veto input
100	-- NIM_In : in STD_LOGIC_VECTOR(2 downto 0); -- auxiliary inputs
101
102	-- on IO-Bank 0
103	-- NIM_In3_GCLK : in STD_LOGIC; -- input with global clock buffer available
104
105
106
107	-- LEDs on IO-Banks 0 and 3
108	-------------------------------------------------------------------------------
109	LED_red : out STD_LOGIC_VECTOR(3 downto 0); -- red
110	LED_ye : out STD_LOGIC_VECTOR(1 downto 0); -- yellow
111	LED_gn : out STD_LOGIC_VECTOR(1 downto 0); -- green
112
113	-- Clock conditioner LMK03000
114	-- on IO-Bank 3
115	-------------------------------------------------------------------------------
116	-- CLK_Clk_Cond : out STD_LOGIC; -- clock conditioner MICROWIRE interface clock
117	-- LE_Clk_Cond : out STD_LOGIC; -- clock conditioner MICROWIRE interface latch enable
118	-- DATA_Clk_Cond : out STD_LOGIC; -- clock conditioner MICROWIRE interface data
119
120	-- SYNC_Clk_Cond : out STD_LOGIC; -- clock conditioner global clock synchronization
121	-- LD_Clk_Cond : in STD_LOGIC; -- clock conditioner lock detect
122
123	-- various RS-485 Interfaces
124	-- on IO-Bank 3
125	-------------------------------------------------------------------------------
126	-- Bus 1: FTU slow control
127	Bus1_Tx_En : out STD_LOGIC; -- bus 1: transmitter enable
128	Bus1_Rx_En : out STD_LOGIC; -- bus 1: receiver enable
129
130	Bus1_RxD_0 : in STD_LOGIC; -- crate 0
131	Bus1_TxD_0 : out STD_LOGIC
132
133	-- Bus1_RxD_1 : in STD_LOGIC; -- crate 1
134	-- Bus1_TxD_1 : out STD_LOGIC;
135
136	-- Bus1_RxD_2 : in STD_LOGIC; -- crate 2
137	-- Bus1_TxD_2 : out STD_LOGIC;
138
139	-- Bus1_RxD_3 : in STD_LOGIC; -- crate 3
140	-- Bus1_TxD_3 : out STD_LOGIC;
141
142
143	-- Bus 2: Trigger-ID to FAD boards
144	-- Bus2_Tx_En : out STD_LOGIC; -- bus 2: transmitter enable
145	-- Bus2_Rx_En : out STD_LOGIC; -- bus 2: receiver enable
146
147	-- Bus2_RxD_0 : in STD_LOGIC; -- crate 0
148	-- Bus2_TxD_0 : out STD_LOGIC;
149
150	-- Bus2_RxD_1 : in STD_LOGIC; -- crate 1
151	-- Bus2_TxD_1 : out STD_LOGIC;
152
153	-- Bus2_RxD_2 : in STD_LOGIC; -- crate 2
154	-- Bus2_TxD_2 : out STD_LOGIC;
155
156	-- Bus2_RxD_3 : in STD_LOGIC; -- crate 3
157	-- Bus2_TxD_3 : out STD_LOGIC;
158
159
160	-- auxiliary access
161	-- Aux_Rx_D : in STD_LOGIC; --
162	-- Aux_Tx_D : out STD_LOGIC; --
163	-- Aux_Rx_En : out STD_LOGIC; -- Rx- and Tx enable
164	-- Aux_Tx_En : out STD_LOGIC; -- also for auxiliary Trigger-ID
165
166
167	-- auxiliary Trigger-ID (i.e. to send the Trigger-ID to the counting hut/house/container)
168	-- TrID_Rx_D : in STD_LOGIC; --
169	-- TrID_Tx_D : out STD_LOGIC --
170
171
172	-- Crate-Resets
173	-- on IO-Bank 3
174	-------------------------------------------------------------------------------
175	-- Crate_Res0 : out STD_LOGIC; --
176	-- Crate_Res1 : out STD_LOGIC; --
177	-- Crate_Res2 : out STD_LOGIC; --
178	-- Crate_Res3 : out STD_LOGIC; --
179
180
181	-- Busy signals from the FAD boards
182	-- on IO-Bank 3
183	-------------------------------------------------------------------------------
184	-- Busy0 : in STD_LOGIC; --
185	-- Busy1 : in STD_LOGIC; --
186	-- Busy2 : in STD_LOGIC; --
187	-- Busy3 : in STD_LOGIC; --
188
189
190
191	-- NIM outputs
192	-- on IO-Bank 0
193	-- LVDS output at the FPGA followed by LVDS to NIM conversion stage
194	-------------------------------------------------------------------------------
195	-- calibration
196	-- Cal_NIM1_p : out STD_LOGIC; -- Cal_NIM1+
197	-- Cal_NIM1_n : out STD_LOGIC; -- Cal_NIM1-
198	-- Cal_NIM2_p : out STD_LOGIC; -- Cal_NIM2+
199	-- Cal_NIM2_n : out STD_LOGIC; -- Cal_NIM2-
200
201	-- auxiliarry / spare NIM outputs
202	-- NIM_Out0_p : out STD_LOGIC; -- NIM_Out0+
203	-- NIM_Out0_n : out STD_LOGIC; -- NIM_Out0-
204	-- NIM_Out1_p : out STD_LOGIC; -- NIM_Out1+
205	-- NIM_Out1_n : out STD_LOGIC; -- NIM_Out1-
206
207
208
209	-- fast control signal outputs
210	-- LVDS output at the FPGA followed by LVDS to NIM conversion stage
211	-- conversion stage
212	-------------------------------------------------------------------------------
213	-- RES_p : out STD_LOGIC; -- RES+ Reset
214	-- RES_n : out STD_LOGIC; -- RES- IO-Bank 0
215
216	-- TRG_p : out STD_LOGIC; -- TRG+ Trigger
217	-- TRG_n : out STD_LOGIC; -- TRG- IO-Bank 0
218
219	-- TIM_Run_p : out STD_LOGIC; -- TIM_Run+ Time Marker
220	-- TIM_Run_n : out STD_LOGIC; -- TIM_Run- IO-Bank 2
221	-- TIM_Sel : out STD_LOGIC -- Time Marker selector on
222	-- IO-Bank 2
223
224	-- CLD_FPGA : out STD_LOGIC; -- DRS-Clock feedback into FPGA
225
226
227
228	-- LVDS calibration outputs
229	-- on IO-Bank 0
230	-------------------------------------------------------------------------------
231	-- to connector J13
232	-- Cal_0_p : out STD_LOGIC;
233	-- Cal_0_n : out STD_LOGIC;
234	-- Cal_1_p : out STD_LOGIC;
235	-- Cal_1_n : out STD_LOGIC;
236	-- Cal_2_p : out STD_LOGIC;
237	-- Cal_2_n : out STD_LOGIC;
238	-- Cal_3_p : out STD_LOGIC;
239	-- Cal_3_n : out STD_LOGIC;
240
241	-- to connector J12
242	-- Cal_4_p : out STD_LOGIC;
243	-- Cal_4_n : out STD_LOGIC;
244	-- Cal_5_p : out STD_LOGIC;
245	-- Cal_5_n : out STD_LOGIC;
246	-- Cal_6_p : out STD_LOGIC;
247	-- Cal_6_n : out STD_LOGIC;
248	-- Cal_7_p : out STD_LOGIC;
249	-- Cal_7_n : out STD_LOGIC;
250
251
252	-- Testpoints
253	-------------------------------------------------------------------------------
254	-- TP : inout STD_LOGIC_VECTOR(32 downto 0)
255	-- TP_in : in STD_LOGIC_VECTOR(34 downto 33); -- input only
256
257	-- Board ID - inputs
258	-- local board-ID "solder programmable"
259	-- all on 'input only' pins
260	-------------------------------------------------------------------------------
261	-- brd_id : in STD_LOGIC_VECTOR(7 downto 0) -- input only
262	);
263	end FTM_test9;
264
265	architecture Behavioral of FTM_test9 is
266
267	COMPONENT FTM_test9_dcm
268	PORT(
269	CLKIN_IN : IN std_logic;
270	RST_IN : IN std_logic;
271	CLKFX_OUT : OUT std_logic;
272	CLK0_OUT : OUT std_logic;
273	LOCKED_OUT : OUT std_logic
274	);
275	END COMPONENT;
276
277	component FTM_test9_rs485_interface
278	GENERIC(
279	CLOCK_FREQUENCY : integer; -- Hertz
280	BAUD_RATE : integer -- bits / sec
281	);
282	PORT(
283	clk : IN std_logic;
284	-- RS485
285	rx_d : IN std_logic;
286	rx_en : OUT std_logic;
287	tx_d : OUT std_logic;
288	tx_en : OUT std_logic;
289	-- FPGA
290	rx_data : OUT std_logic_vector(7 DOWNTO 0);
291	-- rx_busy : OUT std_logic := '0';
292	rx_valid : OUT std_logic := '0';
293	tx_data : IN std_logic_vector(7 DOWNTO 0);
294	tx_busy : OUT std_logic := '0';
295	tx_start : IN std_logic
296	);
297	end component;
298
299	signal reset_sig : STD_LOGIC := '0'; -- initialize reset to 0 at power up
300	signal clk_50M_sig : STD_LOGIC;
301
302	signal LED_red_sig : STD_LOGIC_VECTOR(3 downto 0) := (others => '1');
303	signal LED_ye_sig : STD_LOGIC_VECTOR(1 downto 0) := (others => '1');
304	signal LED_gn_sig : STD_LOGIC_VECTOR(1 downto 0) := (others => '1');
305
306	signal rx_data_sig : STD_LOGIC_VECTOR(7 DOWNTO 0) := (others => '0');
307	-- signal rx_busy_sig : STD_LOGIC;
308	signal rx_valid_sig : STD_LOGIC;
309
310	signal txcnt : integer range 0 to 28 := 0; -- count 28 1-byte frames
311
312	signal tx_start_sig : std_logic := '0';
313	signal tx_data_sig : std_logic_vector (7 DOWNTO 0) := (others => '0');
314	signal tx_busy_sig : std_logic; -- initialized in FTU_rs485_interface
315
316
317	type FTM_test9_StateType is (INIT, SEND, WAIT_FOR_ANSWER, FINISHED);
318	signal FTM_test9_State : FTM_test9_StateType;
319
320	begin
321
322	Inst_FTM_test9_dcm: FTM_test9_dcm PORT MAP(
323	CLKIN_IN => clk,
324	RST_IN => reset_sig,
325	CLKFX_OUT => clk_50M_sig,
326	CLK0_OUT => open,
327	LOCKED_OUT => open
328	);
329
330	Inst_FTM_test9_rs485_interface : FTM_test9_rs485_interface
331	generic map(
332	CLOCK_FREQUENCY => 50000000,
333	BAUD_RATE => 250000
334	)
335	port map(
336	clk => clk_50M_sig,
337	-- RS485
338	rx_d => Bus1_RxD_0,
339	rx_en => Bus1_Rx_En,
340	tx_d => Bus1_TxD_0,
341	tx_en => Bus1_Tx_En,
342	-- FPGA
343	rx_data => rx_data_sig,
344	-- rx_busy => rx_busy_sig,
345	rx_valid => rx_valid_sig,
346	tx_data => tx_data_sig,
347	tx_busy => tx_busy_sig,
348	tx_start => tx_start_sig
349	);
350
351	--FTM test9 state machine
352
353	FTM_test9_FSM: process (clk_50M_sig)
354	begin
355	if Rising_edge(clk_50M_sig) then
356	case FTM_test9_State is
357
358	when INIT =>
359	LED_red_sig(0) <= '0';
360	LED_ye_sig(0) <= '1';
361	LED_gn_sig(0) <= '1';
362	FTM_test9_State <= SEND;
363
364	when SEND =>
365	LED_red_sig(0) <= '0';
366	LED_ye_sig(0) <= '1';
367	LED_gn_sig(0) <= '1';
368	if tx_busy_sig = '0' then
369	if txcnt = 0 then -- start delimiter
370	txcnt <= txcnt + 1;
371	tx_data_sig <= "01000000";
372	tx_start_sig <= '1';
373	FTM_test9_State <= SEND;
374	elsif txcnt = 1 then -- FTU address
375	txcnt <= txcnt + 1;
376	tx_data_sig <= "00111111";
377	tx_start_sig <= '1';
378	FTM_test9_State <= SEND;
379	elsif txcnt = 2 then -- FTM address
380	txcnt <= txcnt + 1;
381	tx_data_sig <= "11000000";
382	tx_start_sig <= '1';
383	FTM_test9_State <= SEND;
384	elsif txcnt = 3 then -- firmware ID
385	txcnt <= txcnt + 1;
386	tx_data_sig <= "00000001";
387	tx_start_sig <= '1';
388	FTM_test9_State <= SEND;
389	elsif txcnt = 4 then -- command
390	txcnt <= txcnt + 1;
391	tx_data_sig <= "00000000";
392	tx_start_sig <= '1';
393	FTM_test9_State <= SEND;
394	elsif txcnt = 5 then -- data: DAC A low
395	txcnt <= txcnt + 1;
396	tx_data_sig <= "00000000";
397	tx_start_sig <= '1';
398	FTM_test9_State <= SEND;
399	elsif txcnt = 6 then -- data: DAC A high
400	txcnt <= txcnt + 1;
401	tx_data_sig <= "00000000";
402	tx_start_sig <= '1';
403	FTM_test9_State <= SEND;
404	elsif txcnt = 7 then -- data: DAC B low
405	txcnt <= txcnt + 1;
406	tx_data_sig <= "00000000";
407	tx_start_sig <= '1';
408	FTM_test9_State <= SEND;
409	elsif txcnt = 8 then -- data: DAC B high
410	txcnt <= txcnt + 1;
411	tx_data_sig <= "00000000";
412	tx_start_sig <= '1';
413	FTM_test9_State <= SEND;
414	elsif txcnt = 9 then -- data: DAC C low
415	txcnt <= txcnt + 1;
416	tx_data_sig <= "00000000";
417	tx_start_sig <= '1';
418	FTM_test9_State <= SEND;
419	elsif txcnt = 10 then -- data: DAC C high
420	txcnt <= txcnt + 1;
421	tx_data_sig <= "00000000";
422	tx_start_sig <= '1';
423	FTM_test9_State <= SEND;
424	elsif txcnt = 11 then -- data: DAC D low
425	txcnt <= txcnt + 1;
426	tx_data_sig <= "00000000";
427	tx_start_sig <= '1';
428	FTM_test9_State <= SEND;
429	elsif txcnt = 12 then -- data: DAC D high
430	txcnt <= txcnt + 1;
431	tx_data_sig <= "00000000";
432	tx_start_sig <= '1';
433	FTM_test9_State <= SEND;
434	elsif txcnt = 13 then -- data: DAC E low
435	txcnt <= txcnt + 1;
436	tx_data_sig <= "00000000";
437	tx_start_sig <= '1';
438	FTM_test9_State <= SEND;
439	elsif txcnt = 14 then -- data: DAC E high
440	txcnt <= txcnt + 1;
441	tx_data_sig <= "00000000";
442	tx_start_sig <= '1';
443	FTM_test9_State <= SEND;
444	elsif txcnt < (28 - 2) then -- data: not used
445	txcnt <= txcnt + 1;
446	tx_data_sig <= "00000000";
447	tx_start_sig <= '1';
448	FTM_test9_State <= SEND;
449	elsif txcnt = (28 - 2) then -- CRC error counter
450	txcnt <= txcnt + 1;
451	tx_data_sig <= "00000000";
452	tx_start_sig <= '1';
453	FTM_test9_State <= SEND;
454	elsif txcnt = (28 - 1) then -- check sum
455	txcnt <= txcnt + 1;
456	tx_data_sig <= "00011101";
457	tx_start_sig <= '1';
458	FTM_test9_State <= SEND;
459	else -- transmission finished
460	txcnt <= 0;
461	LED_red_sig(0) <= '1';
462	LED_ye_sig(0) <= '0';
463	LED_gn_sig(0) <= '1';
464	FTM_test9_State <= WAIT_FOR_ANSWER;
465	end if;
466	else
467	tx_start_sig <= '0';
468	FTM_test9_State <= SEND;
469	end if;
470
471	when WAIT_FOR_ANSWER =>
472	LED_red_sig(0) <= '1';
473	LED_ye_sig(0) <= '0';
474	LED_gn_sig(0) <= '1';
475	if rx_valid_sig = '1' then
476	LED_red_sig(0) <= '1';
477	LED_ye_sig(0) <= '1';
478	LED_gn_sig(0) <= '0';
479	FTM_test9_State <= FINISHED;
480	else
481	FTM_test9_State <= WAIT_FOR_ANSWER;
482	end if;
483
484	when FINISHED =>
485	LED_red_sig(0) <= '1';
486	LED_ye_sig(0) <= '1';
487	LED_gn_sig(0) <= '0';
488
489	end case;
490	end if;
491	end process FTM_test9_FSM;
492
493	LED_red <= LED_red_sig;
494	LED_ye <= LED_ye_sig;
495	LED_gn <= LED_gn_sig;
496
497	LED_red_sig(3 downto 1) <= "111";
498	LED_ye_sig(1) <= '1';
499	LED_gn_sig(1) <= '1';
500
501	end Behavioral;

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