So:

**One-to-one**: you could use a `Dense`

layer as you are not processing sequences:

```
model.add(Dense(output_size, input_shape=input_shape))
```

**One-to-many**: this option is not supported well as chaining models is not very easy in `Keras`

, so the following version is the easiest one:

```
model.add(RepeatVector(number_of_times, input_shape=input_shape))
model.add(LSTM(output_size, return_sequences=True))
```

**Many-to-one**: actually, your code snippet is (almost) an example of this approach:

```
model = Sequential()
model.add(LSTM(1, input_shape=(timesteps, data_dim)))
```

**Many-to-many**: This is the easiest snippet when the length of the input and output matches the number of recurrent steps:

```
model = Sequential()
model.add(LSTM(1, input_shape=(timesteps, data_dim), return_sequences=True))
```

**Many-to-many when number of steps differ from input/output length**: this is freaky hard in Keras. There are no easy code snippets to code that.

**EDIT: Ad 5**

In one of my recent applications, we implemented something which might be similar to *many-to-many* from the 4th image. In case you want to have a network with the following architecture (when an input is longer than the output):

```
O O O
| | |
O O O O O O
| | | | | |
O O O O O O
```

You could achieve this in the following manner:

```
model = Sequential()
model.add(LSTM(1, input_shape=(timesteps, data_dim), return_sequences=True))
model.add(Lambda(lambda x: x[:, -N:, :])) #Select last N from output
```

Where `N`

is the number of last steps you want to cover (on image `N = 3`

).

From this point getting to:

```
O O O
| | |
O O O O O O
| | |
O O O
```

is as simple as artificial padding sequence of length `N`

using e.g. with `0`

vectors, in order to adjust it to an appropriate size.