Below is a practical, engineering-style implementation scheme for connecting an [FPGA](https://www.ampheo.com/c/fpgas-field-programmable-gate-array) to a MIPI interface. In practice “MIPI” almost always means: * MIPI CSI-2 (camera sensors → FPGA), or * MIPI DSI (FPGA → display panel) And both typically run over MIPI D-PHY (the physical layer).  **1) First decision: Does your FPGA have a real MIPI D-PHY (hard PHY) or not?** **Scheme A — FPGA with (hard) MIPI D-PHY support (cleanest)** Pick an FPGA family that is designed for MIPI bridging/vision and provides D-PHY + CSI-2/DSI IP. Example: Lattice CrossLink / CrossLink-NX are positioned specifically as low-power “video bridging” FPGAs and advertise fast MIPI D-PHY bridging solutions. Lattice also offers a CSI-2/DSI D-PHY Receiver IP (soft/hard D-PHY options and multi-lane support). **Block diagram (CSI-2 camera in):** ``` MIPI Sensor (CSI-2 over D-PHY) │ (Clk + N data lanes) ▼ [ D-PHY RX (hard/soft) ] ▼ [ CSI-2 Packet Layer ] - lane align / deskew - ECC/CRC check - virtual channel, data-type decode ▼ [ Pixel/AXI-Stream ] ▼ [ ISP / DMA / DDR Framebuffer / ML ] ``` **Block diagram (DSI display out):** `[ Video / Framebuffer ] -> [ DSI Packetizer + Timing ] -> [ D-PHY TX ] -> MIPI DSI Panel` If you’re on [AMD](https://www.ampheo.com/manufacturer/amd)/Xilinx, this is the typical model: MIPI CSI-2 Receiver Subsystem captures camera data and outputs it as AXI-based streams. The associated MIPI D-PHY core provides the D-PHY RX interface and deskew support for higher line rates (implementation differs by device family). (Also note: some vendor example designs/IP flows may require specific licenses. ) **Scheme B — FPGA WITHOUT MIPI D-PHY (very common): use an external bridge/PHY** Most general-purpose FPGAs cannot directly terminate/handle D-PHY reliably at high speed without dedicated PHY/IP support see above. So you insert a bridge chip that converts MIPI to something “FPGA-friendly” (parallel RGB, LVDS, etc.). **B1) Camera (CSI-2) → FPGA (no D-PHY): use CSI-2-to-Parallel bridge** A standard option is a CSI-2/parallel bridge such as Toshiba TC358746, which can be configured as CSI-2 receiver or transmitter and bridges CSI-2 to a 24-bit parallel port (and the reverse direction). **Typical block diagram:** ``` MIPI CSI-2 Camera │ (D-PHY) ▼ [ TC358746 (CSI-2 RX) ] --> 24-bit Parallel (RGB/YUV/RAW) + PCLK/HS/VS │ I2C/SPI control ▼ FPGA (parallel capture) -> processing -> storage/output ``` This scheme is popular when: * your FPGA has lots of GPIO but no D-PHY, * lane rate is high and you don’t want a risky “soft D-PHY” hack, * you want simpler FPGA RTL (parallel video capture is straightforward). **B2) FPGA → Display panel (DSI) without implementing DSI: use DSI-to-LVDS/eDP bridge** If your output is a laptop-style LCD that accepts LVDS (or you can convert), a bridge like [TI](https://www.ampheo.com/manufacturer/texas-instruments) [SN65DSI83](https://www.onzuu.com/search/SN65DSI83) accepts MIPI DSI (D-PHY, up to 4 lanes) and outputs LVDS (FlatLink). **Typical block diagram:** ``` FPGA RGB (parallel) + timing ▼ [ DSI Bridge (e.g., SN65DSI83) ] <- (if it expects DSI) OR -> LVDS panel ``` (Depending on the bridge direction you need, you pick the right part; SN65DSI83 is specifically a DSI-to-LVDS bridge with a D-PHY receiver. ) **Scheme C — “Soft D-PHY / resistor network” (only for narrow cases)** There are community/legacy approaches that split HS/LP signaling into LVDS + LVCMOS and attempt D-PHY compatibility on some FPGA I/O banks, but this is speed/robustness limited and usually not what you choose for a product unless you’ve proven it thoroughly. (Good for experiments; risky for production.) **2) Hardware connection rules that matter (regardless of scheme)** **CSI-2 / DSI wiring basics** * One Clock lane + 1/2/4 data lanes (most common) * Short, impedance-controlled differential routing (typically ~100 Ω differential), good return paths, ESD protection near [connector](https://www.onzuu.com/category/connector-interconnects) * Keep pair lengths matched within each differential pair; keep lane-to-lane skew controlled if you’re pushing high lane rates **Power/IO domains on bridge/PHY chips** Bridges often have a dedicated MIPI D-PHY core supply (commonly 1.2 V) plus I/O supplies for control/parallel ports. For example, TC358746 lists separate supplies (core/D-PHY vs I/O). **3) FPGA design blocks you’ll implement (CSI-2 example)** If you have CSI-2 coming into the FPGA (either directly via D-PHY IP, or indirectly via a bridge output), your internal pipeline usually looks like: 1. Lane capture / deserialization (or parallel capture) 2. Packet parsing * detect frame start/end * handle virtual channels and data types * validate ECC/CRC (often handled by vendor IP) 3. Pixel unpacking RAW10/12 packing → pixel words 4. Line/frame buffering * FIFO for line * DDR frame buffer if you need random access / scaling 5. Processing ISP (debayer, color correction) or ML/[DSP](https://www.ampheo.com/c/dsp-digital-signal-processors) 6. Output HDMI/DP, LVDS, Ethernet streaming, PCIe, etc. On AMD/Xilinx, the CSI-2 RX subsystem explicitly targets this style of output by providing AXI4-based sensor data out of the subsystem. **4) Quick “which scheme should I choose?” guide** * You want the simplest BOM + highest performance and can choose FPGA family → Scheme A (FPGA with D-PHY + CSI-2/DSI IP) * You already have a mainstream [FPGA](https://www.ampheoelec.de/c/fpgas-field-programmable-gate-array) without D-PHY and just need it to work → Scheme B (external MIPI bridge/PHY) using CSI-2↔Parallel bridges like TC358746 and/or DSI bridges like SN65DSI83 for display conversion * You’re prototyping for learning at modest speeds → Scheme C can be explored, but expect edge cases.