Papan Pangembangan FPGA ALINX AC7Z020 ZYNQ7000

Informasi produk

Papan Pangembangan FPGA ZYNQ7000 minangka papan pangembangan sing nduweni chip XC7Z100-1CLG400I, yaiku bagean saka seri ZYNQ7000. Wis prosesor aplikasi basis CortexA9 dual-inti ARM karo kacepetan jam nganti 800MHz, 256KB ing-chip RAM, lan antarmuka panyimpenan external sing ndhukung 16/32 dicokot DDR2, antarmuka DDR3. Papan uga wis loro Gigabit NIC support, loro USB2.0 antarmuka OTG, loro antarmuka bis CAN2.0B, loro kertu SD, SDIO, MMC kompatibel pengontrol, 2 SPI, 2 UART, 2 antarmuka I2C, lan 4 pasangan 32bit GPIO. Papan kasebut nduweni papan inti (AC7Z010) sing nggunakake rong chip Micron MT41K128M16TW-107 DDR3 kanthi kapasitas gabungan 256MB lan ambane bus data 32-bit. Papan kasebut uga duwe LED pangguna, tombol pangguna, header ekspansi, JTAG port debug, lan sumber daya.

Pandhuan Panggunaan Produk

Kanggo nggunakake Papan Pangembangan FPGA ZYNQ7000, tindakake langkah iki:

1. Sambungake sumber daya menyang papan.
2. Sambungake papan menyang komputer nggunakake kabel USB.
3. Instal sembarang driver sing perlu kanggo Papan ing komputer.
4. Bukak lingkungan pangembangan piranti lunak lan gawe proyek anyar.
5. Ngatur setelan project kanggo nggunakake ZYNQ7000 FPGA Development Board.
6. Tulis kode lan kompilasi.
7. Unggah kode kompilasi menyang papan nggunakake JTAG port debug.
8. Tes kode sampeyan ing papan.

Cathetan: Deleng manual pangguna kanggo informasi sing luwih rinci babagan fitur lan panggunaan papan kasebut.

Versi Rekam

Versi	Tanggal	Rilis Miturut	Katrangan
Rev 1.0	2019-12-15	Rachel Zhou	Rilis pisanan

Papan inti AC7Z010

Papan inti AC7Z010 Pambuka

• AC7Z010 (model papan inti, padha ing ngisor iki) Papan inti FPGA, chip ZYNQ adhedhasar XC7Z010-1CLG400I saka seri XILINX perusahaan ZYNQ7000. Sistem PS chip ZYNQ nggabungake rong prosesor ARM CortexTM-A9, interkoneksi AMBA®, memori internal, antarmuka memori eksternal lan periferal. FPGA saka chip ZYNQ ngemot akeh sel logika sing bisa diprogram, DSP lan RAM internal.
• Papan inti iki nggunakake rong chip Micron MT41K128M16TW-107 DDR3, sing saben duwe kapasitas 256MB; loro Kripik DDR gabungke kanggo mbentuk 32-dicokot data bus jembaré, lan frekuensi jam saka maca lan nulis data antarane ZYNQ lan DDR3 Nganti 533Mhz; konfigurasi iki bisa nyukupi kabutuhan Processing data bandwidth dhuwur sistem
• Kanggo nyambungake karo papan operator, loro konektor papan-kanggo-papan saka papan inti iki ditambahi karo port USB ing sisih PS, antarmuka Gigabit Ethernet, slot kertu SD, lan port MIO liyane (48). Uga meh kabeh port IO (100) BANK13 (mung kanggo AC7Z010), BAN34 lan BANK35 ing sisih PL, tingkat IO saka BANK34 lan BANK35 bisa diwenehake liwat papan operator kanggo nyukupi syarat pangguna kanggo antarmuka tingkat sing beda. Kanggo pangguna sing butuh akeh IO, papan inti iki bakal dadi pilihan sing apik. Lan bagean sambungan IO, chip ZYNQ kanggo antarmuka antarane dawa witjaksono lan Processing diferensial, lan ukuran Papan inti mung 35 * 42 (mm), kang cocok banget kanggo pembangunan secondary.

ZYNQ Chip

Papan inti FPGA AC7Z010 nggunakake chip seri Zynq7000 Xilinx, modul XC7Z010-1CLG400I. Sistem PS chip kasebut nggabungake rong prosesor ARM Cortex™-A9, sambungan AMBA®, memori internal, antarmuka memori eksternal lan periferal. peripheral iki utamané kalebu antarmuka bus USB, antarmuka Ethernet, SD / SDIO antarmuka, antarmuka bis I2C, antarmuka bis CAN, antarmuka UART, GPIO etc. PS bisa operate independen lan miwiti ing daya utawa ngreset. Figure 2-2-1 rinci Sakabèhé Block Diagram saka ZYNQ7000 Chip.

Parameter utama bagean sistem PS yaiku:

• Prosesor aplikasi basis CortexA9 dual-inti ARM, arsitektur ARM-v7, nganti 800MHz
• 32KB level 1 instruksi lan cache data saben CPU, 512KB level 2 cache 2 enggo bareng CPU
• ROM boot on-chip lan RAM on-chip 256KB
• Antarmuka panyimpenan eksternal, ndhukung 16/32 bit DDR2, antarmuka DDR3
• Dhukungan loro Gigabit NIC: DMA agregat divergen, GMII, RGMII, antarmuka SGMII
• Loro antarmuka USB2.0 OTG, saben ndhukung nganti 12 simpul
• Loro antarmuka bis CAN2.0B
• Loro kertu SD, SDIO, pengontrol kompatibel MMC
• 2 SPI, 2 UART, 2 antarmuka I2C
• 4 pasang GPIO 32bit, 54 (32 + 22) minangka sistem PS IO, 64 disambungake menyang PL
• Sambungan bandwidth dhuwur ing PS lan PS menyang PL

Parameter utama bagean logika PL yaiku:

• Sel Logika: 28K
• Look-up-tabel (LUTs): 17600
• Sandal jepit: 35,200
• 18x25MACCs: 80
• Blok RAM: 240 KB
• Loro konverter AD kanggo on-chip voltage, suhu sensing lan munggah 17 saluran input diferensial external, 1MBPS
• XC7Z100-1CLG400I kelas kacepetan chip -1, kelas industri, paket BGA400, pin pitch 0.8mm definisi model chip spesifik seri ZYNQ7000 ditampilake ing Gambar 2-2-2

DDR3 DRAM

• Papan inti FPGA AC7Z010 dilengkapi karo rong chip Micron DDR3 SDRAM (total 1GB), model MT41K128M16TW-107 (Kompatibel karo Hynix).
• H5TQ2G63AFR-PBI). Jembaré bus total DDR3 SDRAM punika 32bit. DDR3 SDRAM makaryakke ing kacepetan maksimum 533MHz (data rate1066Mbps). Sistem memori DDR3 langsung disambungake menyang antarmuka memori BANK 502 saka ZYNQ Processing System (PS). Konfigurasi spesifik DDR3 SDRAM ditampilake ing Tabel 2-3-1 ing ngisor iki:

Nomer Bit	Model Chip	Kapasitas	Pabrik
U8,U9	MT41K128M16TW-107	256M x 16 bit	Mikron

Tabel 2-3-1: Konfigurasi DDR3 SDRAM

Desain hardware DDR3 mbutuhake pertimbangan ketat integritas sinyal. Kita wis kebak dianggep resistor cocog / resistance terminal, tilak kontrol impedansi, lan tilak kontrol dawa ing desain sirkuit lan desain PCB kanggo mesthekake dhuwur-kacepetan lan operasi stabil saka DDR3.

Tugas pin DRAM DDR3:

Jeneng Sinyal	Jeneng Pin ZYNQ	Nomer Pin ZYNQ
DDR3_DQS0_P	PS_DDR_DQS_P0_502	C2
DDR3_DQS0_N	PS_DDR_DQS_N0_502	B2
DDR3_DQS1_P	PS_DDR_DQS_P1_502	G2
DDR3_DQS1_N	PS_DDR_DQS_N1_502	F2
DDR3_DQS2_P	PS_DDR_DQS_P2_502	R2
DDR3_DQS2_N	PS_DDR_DQS_N2_502	T2
DDR3_DQS3_P	PS_DDR_DQS_P3_502	W5
DDR3_DQS4_N	PS_DDR_DQS_N3_502	W4
DDR3_D0	PS_DDR_DQ0_502	C3
DDR3_D1	PS_DDR_DQ1_502	B3
DDR3_D2	PS_DDR_DQ2_502	A2
DDR3_D3	PS_DDR_DQ3_502	A4
DDR3_D4	PS_DDR_DQ4_502	D3
DDR3_D5	PS_DDR_DQ5_502	D1
DDR3_D6	PS_DDR_DQ6_502	C1
DDR3_D7	PS_DDR_DQ7_502	E1
DDR3_D8	PS_DDR_DQ8_502	E2
DDR3_D9	PS_DDR_DQ9_502	E3

DDR3_D10	PS_DDR_DQ10_502	G3
DDR3_D11	PS_DDR_DQ11_502	H3
DDR3_D12	PS_DDR_DQ12_502	J3
DDR3_D13	PS_DDR_DQ13_502	H2
DDR3_D14	PS_DDR_DQ14_502	H1
DDR3_D15	PS_DDR_DQ15_502	J1
DDR3_D16	PS_DDR_DQ16_502	P1
DDR3_D17	PS_DDR_DQ17_502	P3
DDR3_D18	PS_DDR_DQ18_502	R3
DDR3_D19	PS_DDR_DQ19_502	R1
DDR3_D20	PS_DDR_DQ20_502	T4
DDR3_D21	PS_DDR_DQ21_502	U4
DDR3_D22	PS_DDR_DQ22_502	U2
DDR3_D23	PS_DDR_DQ23_502	U3
DDR3_D24	PS_DDR_DQ24_502	V1
DDR3_D25	PS_DDR_DQ25_502	Y3
DDR3_D26	PS_DDR_DQ26_502	W1
DDR3_D27	PS_DDR_DQ27_502	Y4
DDR3_D28	PS_DDR_DQ28_502	Y2
DDR3_D29	PS_DDR_DQ29_502	W3
DDR3_D30	PS_DDR_DQ30_502	V2
DDR3_D31	PS_DDR_DQ31_502	V3
DDR3_DM0	PS_DDR_DM0_502	A1
DDR3_DM1	PS_DDR_DM1_502	F1
DDR3_DM2	PS_DDR_DM2_502	T1
DDR3_DM3	PS_DDR_DM3_502	Y1
DDR3_A0	PS_DDR_A0_502	N2
DDR3_A1	PS_DDR_A1_502	K2
DDR3_A2	PS_DDR_A2_502	M3
DDR3_A3	PS_DDR_A3_502	K3
DDR3_A4	PS_DDR_A4_502	M4
DDR3_A5	PS_DDR_A5_502	L1
DDR3_A6	PS_DDR_A6_502	L4
DDR3_A7	PS_DDR_A7_502	K4
DDR3_A8	PS_DDR_A8_502	K1
DDR3_A9	PS_DDR_A9_502	J4

DDR3_A10	PS_DDR_A10_502	F5
DDR3_A11	PS_DDR_A11_502	G4
DDR3_A12	PS_DDR_A12_502	E4
DDR3_A13	PS_DDR_A13_502	D4
DDR3_A14	PS_DDR_A14_502	F4
DDR3_BA0	PS_DDR_BA0_502	L5
DDR3_BA1	PS_DDR_BA1_502	R4
DDR3_BA2	PS_DDR_BA2_502	J5
DDR3_S0	PS_DDR_CS_B_502	N1
DDR3_RAS	PS_DDR_RAS_B_502	P4
DDR3_CAS	PS_DDR_CAS_B_502	P5
DDR3_WE	PS_DDR_WE_B_502	M5
DDR3_ODT	PS_DDR_ODT_502	N5
DDR3_RESET	PS_DDR_DRST_B_502	B4
DDR3_CLK0_P	PS_DDR_CKP_502	L2
DDR3_CLK0_N	PS_DDR_CKN_502	M2
DDR3_CKE	PS_DDR_CKE_502	N3

QSPI Flash

Papan inti FPGA AC7Z010 dilengkapi chip FLASH Quad-SPI 256MBit, model lampu kilat yaiku W25Q256FVEI, sing nggunakake 3.3V CMOS voltage standar. Amarga sifat non-molah malih saka QSPI FLASH, bisa digunakake minangka piranti boot kanggo sistem kanggo nyimpen gambar boot saka sistem. Gambar kasebut utamane kalebu bit FPGA files, kode aplikasi ARM, lan data pangguna liyane files. Model spesifik lan paramèter sing gegandhengan karo QSPI FLASH ditampilake ing Tabel 2-4-1.

posisi	Model	Kapasitas	Pabrik
U15	W25Q256FVEI	32M Byte	Winbond

Tabel 2-4-1: Spesifikasi QSPI FLASH
QSPI FLASH disambungake menyang port GPIO saka BANK500 ing bagean PS saka chip ZYNQ. Ing desain sistem, fungsi port GPIO saka port PS iki kudu dikonfigurasi minangka antarmuka FLASH QSPI. Gambar 2-4-1 nuduhake Flash QSPI ing skema.

Konfigurasi tugas pin chip:

Jeneng Sinyal	Jeneng Pin ZYNQ	Nomer Pin ZYNQ
QSPI_SCK	PS_MIO6_500	A5
QSPI_CS	PS_MIO1_500	A7
QSPI_D0	PS_MIO2_500	B8
QSPI_D1	PS_MIO3_500	D6
QSPI_D2	PS_MIO4_500	B7
QSPI_D3	PS_MIO5_500	A6

Konfigurasi jam

Papan inti AC7Z010 nyedhiyakake jam aktif kanggo sistem PS, supaya sistem PS bisa mlaku kanthi mandiri.
Sumber jam sistem PS
Chip ZYNQ nyedhiyakake input jam 33.333333MHz kanggo bagean PS liwat kristal X1 ing papan inti. Input jam disambungake menyang pin PS_CLK_500 saka chip ZYNQ BANK500. Diagram skematis kasebut ditampilake ing Gambar 2-5-1:

Tugas pin jam:

Jeneng sinyal	Pin ZYNQ
PS_CLK_500	E7

Power Supply
Sumber daya voltage Papan inti AC7Z010 punika DC5V, kang diwenehake dening nyambungake Papan operator. Kajaba iku, kekuwatan BANK34 lan BANK35 uga diwenehake liwat papan operator. Diagram skematis desain sumber daya ing papan inti ditampilake ing Gambar 2-6-1:

Papan pangembangan FPGA didhukung dening + 5V, lan diowahi dadi + 1.0V, + 1.8V, + 1.5V, + 3.3V papat sumber daya liwat papat chip daya DC / DC. Output saiki + 1.0V bisa tekan 6A, + 1.8V lan + 1.5V daya output saiki 3A, + 3.3V output saiki 500mA. J29 uga duwe 4 pin saben kanggo nyuplai daya menyang FPGA BANK34 lan BANK35. Standar yaiku 3.3V. Pangguna bisa ngganti daya BANK34 lan BANK35 kanthi ngganti VCCIO34 lan VCCIO35 ing backplane. 1.5V ngasilake VTT lan VREF voltagsing dibutuhake dening DDR3 liwat TPS51206 TI. Fungsi saben distribusi daya ditampilake ing tabel ing ngisor iki:

Power Supply	Fungsi
+1.0V	ZYNQ PS lan PL bagean Inti Voltage
+1.8V	ZYNQ PS lan PL parsial tambahan voltage BANK501 IO voltage
+3.3V	ZYNQ Bank0, Bank500, QSIP FLASH Jam Kristal Kab

+1.5V	DDR3, ZYNQ Bank501
VREF,VTT(+0.75V)	DDR3
VCCIO34/35	Bank34, Bank35

Amarga sumber daya saka ZYNQ FPGA nduweni syarat urutan daya, ing desain sirkuit, kita wis dirancang miturut syarat daya chip. Urutan power-on yaiku + 1.0V-> + 1.8V-> (+1.5 V, +3.3V, VCCIO) desain sirkuit kanggo mesthekake operasi normal chip. Amarga standar tingkat BANK34 lan BANK35 ditemtokake dening sumber daya sing diwenehake dening papan operator, sing paling dhuwur yaiku 3.3V. Nalika sampeyan ngrancang papan operator kanggo nyedhiyakake daya VCCIO34 lan VCCIO35 kanggo papan inti, urutan daya luwih alon tinimbang + 5V.

Ukuran Papan Inti AC7Z010

Papan kanggo Papan Konektor pin assignment
Papan inti wis total rong bandar expansion dhuwur-kacepetan. Iku nggunakake loro 120-pin konektor antar-papan (J29 / J30) kanggo nyambung menyang Papan operator. Jarak PIN saka papan kanggo konektor papan yaiku 0.5mm, ing antarane, J29 disambungake menyang daya 5V, input daya VCCIO, sawetara sinyal IO lan JTAG sinyal, lan J30 disambungake menyang sinyal IO isih lan MIO. Tingkat IO saka BANK34 lan BANK35 bisa diganti kanthi nyetel input VCCIO ing konektor, tingkat paling dhuwur ora ngluwihi 3.3V. Papan operator AX7Z010 sing dirancang yaiku 3.3V kanthi standar. Elinga yen IO saka BANK13 ora

Pin assignment saka Papan kanggo konektor Papan J29

J29 Pin	Sinyal  jeneng	Pin ZYNQ Nomer	J29 Pin	Jeneng Sinyal	Pin ZYNQ Nomer
1	VCC5V	–	2	VCC5V	–
3	VCC5V	–	4	VCC5V	–
5	VCC5V	–	6	VCC5V	–
7	VCC5V	–	8	VCC5V	–
9	GND	–	10	GND	–
11	VCCIO_34	–	12	VCCIO_35	–
13	VCCIO_34	–	14	VCCIO_35	–
15	VCCIO_34	–	16	VCCIO_35	–
17	VCCIO_34	–	18	VCCIO_35	–
19	GND	–	20	GND	–
21	IO34_L10P	V15	22	IO34_L7P	Y16
23	IO34_L10N	W15	24	IO34_L7N	Y17
25	IO34_L15N	U20	26	IO34_L17P	Y18
27	IO34_L15P	T20	28	IO34_L17N	Y19
29	GND	–	30	GND	–
31	IO34_L9N	U17	32	IO34_L8P	W14
33	IO34_L9P	T16	34	IO34_L8N	Y14
35	IO34_L12N	U19	36	IO34_L3P	U13
37	IO34_L12P	U18	38	IO34_L3N	V13
39	GND	–	40	GND	–
41	IO34_L14N	P20	42	IO34_L21N	V18
43	IO34_L14P	N20	44	IO34_L21P	V17
45	IO34_L16N	W20	46	IO34_L18P	V16
47	IO34_L16P	V20	48	IO34_L18N	W16
49	GND	–	50	GND	–
51	IO34_L22N	W19	52	IO34_L23P	N17
53	IO34_L22P	W18	54	IO34_L23N	P18
55	IO34_L20N	R18	56	IO34_L13N	P19
57	IO34_L20P	T17	58	IO34_L13P	N18
59	GND	–	60	GND	–

61	IO34_L19N	R17	62	IO34_L11N	U15
63	IO34_L19P	R16	64	IO34_L11P	U14
65	IO34_L24P	P15	66	IO34_L5N	T15
67	IO34_L24N	P16	68	IO34_L5P	T14
69	GND	–	70	GND	–
71	IO34_L4P	V12	72	IO34_L2N	U12
73	IO34_L4N	W13	74	IO34_L2P	T12
75	IO34_L1P	T11	76	IO34_L6N	R14
77	IO34_L1N	T10	78	IO34_L6P	P14
79	GND	–	80	GND	–
81	IO13_L13P	Y7	82	IO13_L21P	V11
83	IO13_L13N	Y6	84	IO13_L21N	V10
85	IO13_L11N	V7	86	IO13_L14N	Y8
87	IO13_L11P	U7	88	IO13_L14P	Y9
89	GND	–	90	GND	–
91	IO13_L19N	U5	92	IO13_L22N	W6
93	IO13_L19P	T5	94	IO13_L22P	V6
95	IO13_L16P	W10	96	IO13_L15P	V8
97	IO13_L16N	W9	98	IO13_L15N	W8
99	GND	–	100	GND	–
101	IO13_L17P	U9	102	IO13_L20P	Y12
103	IO13_L17N	U8	104	IO13_L20N	Y13
105	IO13_L18P	W11	106	IO13_L12N	U10
107	IO13_L18N	Y11	108	IO13_L12P	T9
109	GND	–	110	GND	–
111	FPGA_TCK	F9	112	VP	K9
113	FPGA_TMS	J6	114	VN	L10
115	FPGA_TDO	F6	116	PS_POR_B	C7
117	FPGA_TDI	G6	118	FPGA_DONE	R11

Pin assignment saka Papan kanggo konektor Papan J30

J30 Pin	Jeneng Sinyal	Pin ZYNQ Nomer	J30 Pin	Jeneng Sinyal	ZYNQ Nomer Pin
1	IO35_L1P	C20	2	IO35_L15N	F20

3	IO35_L1N	B20	4	IO35_L15P	F19
5	IO35_L18N	G20	6	IO35_L5P	E18
7	IO35_L18P	G19	8	IO35_L5N	E19
9	GND	T13	10	GND	T13
11	IO35_L10N	J19	12	IO35_L3N	D18
13	IO35_L10P	K19	14	IO35_L3P	E17
15	IO35_L2N	A20	16	IO35_L4P	D19
17	IO35_L2P	B19	18	IO35_L4N	D20
19	GND	T13	20	GND	T13
21	IO35_L8P	M17	22	IO35_L9N	L20
23	IO35_L8N	M18	24	IO35_L9P	L19
25	IO35_L7P	M19	26	IO35_L6P	F16
27	IO35_L7N	M20	28	IO35_L6N	F17
29	GND	T13	30	GND	T13
31	IO35_L17N	H20	32	IO35_L16N	G18
33	IO35_L17P	J20	34	IO35_L16P	G17
35	IO35_L19N	G15	36	IO35_L13N	H17
37	IO35_L19P	H15	38	IO35_L13P	H16
39	GND	T13	40	GND	T13
41	IO35_L12N	K18	42	IO35_L14N	H18
43	IO35_L12P	K17	44	IO35_L14P	J18
45	IO35_L24N	J16	46	IO35_L20P	K14
47	IO35_L24P	K16	48	IO35_L20N	J14
49	GND	T13	50	GND	T13
51	IO35_L21N	N16	52	IO35_L11P	L16
53	IO35_L21P	N15	54	IO35_L11N	L17
55	IO35_L22N	L15	56	IO35_L23P	M14
57	IO35_L22P	L14	58	IO35_L23N	M15
59	GND	T13	60	GND	T13
61	PS_MIO22	B17	62	PS_MIO50	B13
63	PS_MIO27	D13	64	PS_MIO45	B15
65	PS_MIO23	D11	66	PS_MIO46	D16
67	PS_MIO24	A16	68	PS_MIO41	C17
69	GND	T13	70	GND	T13
71	PS_MIO25	F15	72	PS_MIO7	D8
73	PS_MIO26	A15	74	PS_MIO12	D9

75	PS_MIO21	F14	76	PS_MIO10	E9
77	PS_MIO16	A19	78	PS_MIO11	C6
79	GND	T13	80	GND	T13
81	PS_MIO20	A17	82	PS_MIO9	B5
83	PS_MIO19	D10	84	PS_MIO14	C5
85	PS_MIO18	B18	86	PS_MIO8	D5
87	PS_MIO17	E14	88	PS_MIO0	E6
89	GND	T13	90	GND	T13
91	PS_MIO39	C18	92	PS_MIO13	E8
93	PS_MIO38	E13	94	PS_MIO47	B14
95	PS_MIO37	A10	96	PS_MIO48	B12
97	PS_MIO28	C16	98	PS_MIO49	C12
99	GND	T13	100	GND	T13
101	PS_MIO35	F12	102	PS_MIO52	C10
103	PS_MIO34	A12	104	PS_MIO51	B9
105	PS_MIO33	D15	106	PS_MIO40	D14
107	PS_MIO32	A14	108	PS_MIO44	F13
109	GND	T13	110	GND	T13
111	PS_MIO31	E16	112	PS_MIO15	C8
113	PS_MIO36	A11	114	PS_MIO42	E12
115	PS_MIO29	C13	116	PS_MIO43	A9
117	PS_MIO30	C15	118	PS_MIO53	C11
119	QSPI_D3_PS_MIO5	A6	120	QSPI_D2_PS_MIO4	B7

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Dokumen / Sumber Daya

Papan Pangembangan FPGA ALINX AC7Z020 ZYNQ7000 [pdf] Manual pangguna AC7Z020, AC7Z020 ZYNQ7000 Papan Pengembangan FPGA, Papan Pengembangan FPGA ZYNQ7000, Papan Pengembangan FPGA, Papan Pengembangan, Papan

Referensi

• Manual pangguna