Since A→CGH and Ax→C for any letter x, we can ignore the second of the functional dependencies (AD→C) because it doesn't tell us anything that A→CGH doesn't also tell us.

There is nothing that determines B; there is nothing that determines D.

Since G determines H, and A determines both G and H, we can separate G→H into a relation (there is a transitive dependency A→G and G→H).

```
R1 = { G, H } : PK = { G }
```

That leaves F' = { A→CG, DE→F } and R' = (A, B, C, D, E, F, G).

The two functional dependencies left can form two more relations:

```
R2 = { A, C, G } : PK = { A }
R3 = { D, E, F } : PK = { D, E }
```

That leaves R'' = { A, B, D, E }

```
R4 = { A, B, D, E } : PK = { A, B, D, E }
```

The join of R1, R2, R3, and R4 should leave you with the R you started with for any starting value of R (that satisfies the constraints of the given functional dependencies).