Month: June 2023

An I2C Matrix Keypad

The completed I2C Matrix Keypad

In a previous post this month I introduced my 4×4 matrix keypad. That keypad was designed to be directly interfaced to a microcontroller’s GPIO pins or alternatively to an IO expander chip like the PCF8574. That design, while working very well had the problem of requiring 8 GPIO pins to function correctly.

GPIO pins on a microcontroller can be considered very precious resources, and it should then be logical to assume that we should find a way to use these GPIO pins in a more conservative way, to allow us to interface more peripherals.

I solved this problem by integrating the keypad with an IO Expander on the same PCB. That will allow us to get away with using only 2 GPIO pins, and also open up the option of adding more keypads to the I2C bus, in the event that we need that many keys for a particular project.

The Schematic

I2C 4×4 Matrix Keypad Schematic

Looking closely at the schematic, we can see that it is exactly the same basic keypad circuit that I used in the initial design. The only difference is that in this design, I have integrated a PCF8574 directly onto the PCB.

Some additional features include selectable I2C Pullup resistors ( usually my microcontroller development boards already include those) that can be activated with a jumper when needed. There are also a set of address selection jumpers, making it possible to stack keypads together into a bigger keyboard if you require something like that. Note that, in this version of the hardware, I did not include headers for stacking.

The keypad can be powered by a DC power source of 3.3v to 5v.

The PCB

I2C Keypad PCB
3D Render of the I2C Keypad

The PCB is a double-layer board of 68.8mm x 50.8mm. Male header pins provide access to the connections as well as address and pullup resistor jumpers. In my build, I have mounted these male headers on the back of the PCB. That makes it possible to mount the Keypad in an enclosure without having the jumpers “stick out” and get in the way.

The top layer of the I2C Keypad PCB
Bottom Layer

Manufacturing

I choose PCBWay for my PCB manufacturing.
This month, PCBWay is also celebrating its 9th anniversary, and that means that there are quite a lot of very special offers available.

Why?
What makes them different from the rest?

PCBWay‘s business goal is to be the most professional PCB manufacturer for prototyping and low-volume production work in the world. With more than a decade in the business, they are committed to meeting the needs of their customers from different industries in terms of quality, delivery, cost-effectiveness and any other demanding requests. As one of the most experienced PCB manufacturers and SMT Assemblers in China, they pride themselves to be our (the Makers) best business partners, as well as good friends in every aspect of our PCB manufacturing needs. They strive to make our R&D work easy and hassle-free.

How do they do that?

PCBWay is NOT a broker. That means that they do all manufacturing and assembly themselves, cutting out all the middlemen, and saving us money.

PCBWay’s online quoting system gives a very detailed and accurate picture of all costs upfront, including components and assembly costs. This saves a lot of time and hassle.

PCBWay gives you one-on-one customer support, that answers you in 5 minutes ( from the Website chat ), or by email within a few hours ( from your personal account manager). Issues are really resolved very quickly, not that there are many anyway, but, as we are all human, it is nice to know that when a gremlin rears its head, you have someone to talk to that will do his/her best to resolve your issue as soon as possible.

Find out more here

Assembly

The assembly of this PCB was quite easy and quick. A stencil is not required. All SMD components are 0805 or bigger. It would thus be quite easy to solder them all by hand with a fine-tipped soldering iron.

I have however used soldering paste and hot air to reflow the components, as it is the fastest, in my opinion, and definitely looks neater than hand soldering.

After placing SMD components onto solder paste – ready for reflow soldering
After Reflow soldering with Hot Air

The board is now ready to solder the switches and header pins in place. As already mentioned above, I chose to assemble the headers on the back of the PCB to prevent them from interfering with any enclosure that I may later use with the keypad.

Final Assembly
Note that I assembled the headers onto the back of the PCB.

Testing and Coding

Testing the keypad consisted of a few steps, the first of which was ensuring that there were no short circuits, as well as that all the momentary switches worked.
This was done with a multimeter in continuity as well as diode mode, with probes alternatively on each column and row in turn, while pressing the buttons.

The next stage was testing the I2C IO Expander. This was done with a simple I2C Scanning sketch on an Arduino Uno. It did not do a lot, but, I could see that the PCF8574 is responding to its address and that the pullup resistors work when enabled. This test was repeated with my own ESP8266 and ESP32 boards, this time with pullup resistors disabled, as these boards already have them onboard.

Coding came next, and it was another case of perspectives. It seems like all commercial keypads do not have diodes. This affects the way that they work with a given library. It seems that software developers and hardware developers have different understandings of what a row and a column is.

This meant that, due to the fact that I have diodes on each switch, and the way that the library work – which pins are pulled high and which are set as inputs -, I had to swap around my rows and columns in the software to get everything to work. On a keypad with the diodes replaced with 0-ohm links, that was not needed.

A short test sketch follows below:

Note that with was run on an ESP8266-12E, therefore the Wire.begin() function was changed to Wire.begin(4,5); in order to use GPIO 4 and GPIO 5 for I2C

Another point to note is that the keypad Layout will seem strange. Remember that this is due to the diodes in series on each switch. That forces us to swap around the Rows and the Columns in the software, resulting in a mirrored and rotated left representation of the keypad. It looks funny, but believe me, it actually still works perfectly.

#include <Wire.h>
#include "Keypad.h"
#include <Keypad_I2C.h>

const byte n_rows = 4;
const byte n_cols = 4;

char keys[n_rows][n_cols] = {
    {'1', '4', '7', '*'},
    {'2', '5', '8', '0'},
    {'3', '6', '9', '#'},
    {'A', 'B', 'C', 'D'}};

byte rowPins[n_rows] = {4, 5, 6, 7};
byte colPins[n_cols] = {0, 1, 2, 3};

Keypad_I2C myKeypad = Keypad_I2C(makeKeymap(keys), rowPins, colPins, n_rows, n_cols, 0x20);

String swOnState(KeyState kpadState)
{
    switch (kpadState)
    {
    case IDLE:
        return "IDLE";
        break;
    case PRESSED:
        return "PRESSED";
        break;
    case HOLD:
        return "HOLD";
        break;
    case RELEASED:
        return "RELEASED";
        break;
    } // end switch-case
    return "";
} // end switch on state function

void setup()
{
    // This will be called by App.setup()
    Serial.begin(115200);
    while (!Serial)
    { /*wait*/
    }
    Serial.println("Press any key...");
    Wire.begin(4,5);
    myKeypad.begin(makeKeymap(keys));
}

char myKeyp = NO_KEY;
KeyState myKSp = IDLE;
auto myHold = false;

void loop()
{

    char myKey = myKeypad.getKey();
    KeyState myKS = myKeypad.getState();

    if (myKSp != myKS && myKS != IDLE)
    {
        Serial.print("myKS: ");
        Serial.println(swOnState(myKS));
        myKSp = myKS;
        if (myKey != NULL)
            myKeyp = myKey;
        String r;
        r = myKeyp;
        Serial.println("myKey: " + String(r));
        if (myKS == HOLD)
            myHold = true;
        if (myKS == RELEASED)
        {
            if (myHold)
                r = r + "+";
            Serial.println(r.c_str());
            myHold = false;
        }
        Serial.println(swOnState(myKS));
        myKey == NULL;
        myKS = IDLE;
    }
}

Conclusion

This project once again delivered what I set out to achieve. It has some quirks, but nothing serious. Everything works as expected, both in the Arduino IDE/platform IO realm, as well as in ESPHome. It is worth noting that in ESPHome, we do not need to swap the rows and columns to use the Keypad component. Do remember to leave the has_diodes flag to false though…

ESP32-S DEV Board – Rev 2.0

A few months ago, I started to work on an ESP32-S SOC module in Arduino Uno form factor. This is Revision 2.0 – the ESP32-S Dev Board – Rev 2.0

During the time since I designed, and ultimately had the Rev 1.0 PCB manufactured, It has quickly become one of my go-to development platforms, something that I hoped it would become. It also seemed to be gaining popularity online, with quite a few of them being ordered.

Problems did however arise, as the manufacturer discontinued the SOC module, the AI-Thinker ESP32-S, but, as this was based on the ESP32 WROOM32 from Espressif, which, while still old, was still in production, it was not a serious problem.

Using the Rev 1.0 device was easy enough, but I soon started to experience some irritation, as in my attempts to build a very streamlined device, I left out some add-on components, that now seemed to be a very good idea to have on board…
Let me explain:

In the initial design, I did not include a DC barrel connector, as well as no USB port with a USB-to-serial converter, my argument being that the USB port is usually only used a few times, or at most once, as I usually upload firmware to ESP32’s OTA. Power ( on the bench that is, is usually supplied via a pair of wires, so no dedicated connector seemed to be necessary.

As I proceeded to design addon shields for the device, it became clear that that power connector, at minimum, as well as the standard 2-transistor reset/flash circuit, would be a very very welcome addition to this PCB.

See the pictures below for a comparison of the two boards…

ESP32-S Dev Board Rev 1.0
ESP32-S Dev Board Rev 1.0
ESP32-S Dev board Rev 2.0
ESP32-S Dev Board Rev 2.0

I have also decided to use male header pins on this build, as I sort of like to use them more than the female ones ( which seem to develop connectivity issues after a while – this could be due to the quality of the connector strips that I bought)

What changed, and how?

I made quite a few changes, most of them quite subtle.
The most obvious would be the addition of a DC Barrel connector, to allow the device to be powered easier when used as a permanent project. In addition to this, a 6-pin programming header was added, in order to make flashing the device with an external USB-to-serial adapter easier than usual. ( This means that the standard 2-transistor reset/flash circuit was also added). That meant a slight increase in the component count. Additional decoupling capacitors were also added to add voltage stability to the ESP32-S. The routing of the entire board was also changed, with more attention being paid to the heat dissipation of the ESP32-S module, which tended to get a bit hot.

Power is provided by a 3.3v LDO regulator, the same as in the Rev 1.0 hardware.
I do plan to change this to a small buck converter in the near future, as the 800mA provided by the LDO regulator can get a bit limited, especially when using I2S Audio devices, something which I am doing quite a lot over the last few months.

Manufacturing

I choose PCBWay for my PCB manufacturing.
This month, PCBWay is also celebrating its 9th anniversary, and that means that there are quite a lot of very special offers available.

Why?
What makes them different from the rest?

PCBWay‘s business goal is to be the most professional PCB manufacturer for prototyping and low-volume production work in the world. With more than a decade in the business, they are committed to meeting the needs of their customers from different industries in terms of quality, delivery, cost-effectiveness and any other demanding requests. As one of the most experienced PCB manufacturers and SMT Assemblers in China, they pride themselves to be our (the Makers) best business partners, as well as good friends in every aspect of our PCB manufacturing needs. They strive to make our R&D work easy and hassle-free.

How do they do that?

PCBWay is NOT a broker. That means that they do all manufacturing and assembly themselves, cutting out all the middlemen, and saving us money.

PCBWay’s online quoting system gives a very detailed and accurate picture of all costs upfront, including components and assembly costs. This saves a lot of time and hassle.

PCBWay gives you one-on-one customer support, that answers you in 5 minutes ( from the Website chat ), or by email within a few hours ( from your personal account manager). Issues are really resolved very quickly, not that there are many anyway, but, as we are all human, it is nice to know that when a gremlin rears its head, you have someone to talk to that will do his/her best to resolve your issue as soon as possible.

Find out more here

Assembly

This PCB will definitely benefit from using a stencil, but it is not strictly necessary. I did however get one, as I prefer the uniform solder-paste application and speed that they give me.

Stencil for SMD assembly

Component placing took only about 10 minutes in total, including the time needed to place and use the stencil, apply solder paste, select components and place them in their correct positions.

After Solder paste application – Before reflow soldering

The board was then reflow soldered on a hotplate at 223 degrees Centigrade.

After Reflow soldering

The board was inspected for solder bridges and bad joints, and I then proceeded with through-hole component assembly, which took about another 10 minutes.

ESP32-S Dev board Rev 2.0
The completed PCB

Conclusion

This was definitely a very worthwhile revision on a very useful piece of equipment. The addition of the programming header, in particular, already saves quite a bit of time, and the DC Barrel connector opens up new possibilities for the use of the device outside of the “bench” environment.

A quick P-MOS MOSFET Driver Board

Introduction

A driver is needed to switch a P-Channel MOSFET because the gate of a P-Channel MOSFET needs to be driven to a voltage that is more negative than the source in order to turn it on. This can be difficult to do with low-voltage logic, such as 5V or 3.3V. A driver can provide the necessary voltage and current to turn on the P-Channel MOSFET, even when the logic voltage is low.

Here are some of the benefits of using a driver to switch a P-Channel MOSFET:

  • Increased switching speed: A driver can provide the necessary current to charge and discharge the gate capacitance of the P-Channel MOSFET quickly, which results in faster switching speeds.
  • Reduced power consumption: A driver can help to reduce power consumption by providing the necessary current in a short pulse, rather than a continuous stream of current.
  • Improved noise immunity: A driver can help to improve noise immunity by providing a clean and isolated signal to the gate of the P-Channel MOSFET.

If you are using a P-Channel MOSFET in your circuit, it is a good idea to use a driver to switch it. This will help to ensure that the MOSFET is switched quickly and efficiently and that it is protected from noise.

Here are some of the different types of drivers that can be used to switch P-Channel MOSFETs:

  • Logic level drivers: These drivers are designed to work with low-voltage logic, such as 5V or 3.3V. They typically have a high output voltage, which can be used to drive the gate of a P-Channel MOSFET.
  • High-side drivers: These drivers are designed to provide a high voltage to the gate of a P-Channel MOSFET. They are often used in circuits where the P-Channel MOSFET is used to switch a high-voltage rail.
  • Isolated drivers: These drivers provide an isolated signal to the gate of the P-Channel MOSFET. This is useful in circuits where it is important to prevent noise from entering the circuit.

Why did I decide to design this prototype?

The Story behind the prototype

This driver PCB is part of a solution for a project involving a set of 6v LED lights.
Each of the LED lights requires +/- 300mA @ 6v to operate efficiently.
I want to control these from a Microcontroller, either an ESP32 or even the XIAO RP2040 or similar. The current sink capability of an individual GPIO pin on these microcontrollers is limited, in the case of the RP2040 it is limited to 3mA per pin.

This prototype is an attempt to test out some basic driver ideas that might perform correctly for my particular needs, being

  • To stay within the limitations of the particular microcontroller GPIO current specifications
  • To be able to use any of the particular microcontrollers, without having to design a specific solution tailored to a specific device

The Schematic

I decided to keep things extremely simple to start with, using a very simple circuit consisting of only 4 components per channel. These are :
– an S9013 NPN BJT Transistor, capable of switching up to 500mA of current
– a SI2301 P-Channel Logic Level MOSFET, capable of switching up to 2.3A
– 10k pullup-resitor
– 1k resistor on the base of the BJT


The theory of operation is as follows:
The pullup resistor, R8, keeps the gate of the MOSFET (Q4) positive, thus ensuring that Q4 stays turned off when T4 is turned off. A HIGH signal at B4 will turn on T4, which will in turn pull the gate of Q4 to ground, turning Q4 on in the process.
That will in turn turn on the load ( connected at 4+ and 4- ).

It is important to note here that the value of R8, 10K at the moment, is not finalised, and may change to increase the performance of the circuit.

The PCB

The board was made to fit on a standard breadboard or be used as a standalone module, depending on the position of the male header pins.


Manufacturing


I choose PCBWay for my PCB manufacturing.
This month, PCBWay is also celebrating its 9th anniversary, and that means that there are quite a lot of very special offers available.


Why? What makes them different from the rest?
PCBWay‘s business goal is to be the most professional PCB manufacturer for prototyping and low-volume production work in the world. With more than a decade in the business, they are committed to meeting the needs of their customers from different industries in terms of quality, delivery, cost-effectiveness and any other demanding requests. As one of the most experienced PCB manufacturers and SMT Assemblers in China, they pride themselves to be our (the Makers) best business partners, as well as good friends in every aspect of our PCB manufacturing needs. They strive to make our R&D work easy and hassle-free.

How do they do that?

PCBWay is NOT a broker. That means that they do all manufacturing and assembly themselves, cutting out all the middlemen, and saving us money.

PCBWay’s online quoting system gives a very detailed and accurate picture of all costs upfront, including components and assembly costs. This saves a lot of time and hassle.

PCBWay gives you one-on-one customer support, that answers you in 5 minutes ( from the Website chat ), or by email within a few hours ( from your personal account manager). Issues are really resolved very quickly, not that there are many anyway, but, as we are all human, it is nice to know that when a gremlin rears its head, you have someone to talk to that will do his/her best to resolve your issue as soon as possible.

Find out more here

Assembly

The assembly of the PCB does not require any special tools, and can be done completely by hand if you choose. A very fine-tipped soldering iron should be perfect.

I chose to go the hot-air and solder-paste route, as it is faster, and looks neater in the end. The use of a stencil was not required.

The total assembly took about 5 minutes in total.

Testing

Testing the completed PCB module was performed with one of the LED light modules connected to each MOSFET Channel in turn, and then applying a voltage signal, or ground, to the control pin ( marked A to D on the picture above)

That was followed by connecting an Oscilloscope and Signal Generator to the control pins, as well as the outputs, and observing the waveforms during operation. A square wave output from the signal generator provided the switching signal.

Conclusion

The module works as expected, but the pullup resistor value needs to be fine-tuned to provide a better switching response on the MOSFET at high frequency.
I am however happy with the initial performance, and can now move on to improving the circuit to perform to my specifications.


A Reliable Matrix Keypad

What is a matrix keypad?

A matrix keypad is a type of keypad that uses a matrix of wires to connect the keys to the microcontroller. This allows for a smaller and more compact keypad than a traditional keypad, which uses a single row and column of wires for each key. Matrix keypads are also more reliable than conventional keypads, as they are less susceptible to damage from dirt and moisture.

How does a matrix keypad work?

A matrix keypad is made up of a number of rows and columns of keys. Each key is connected to two wires, one for the row and one for the column. When a key is pressed, it completes a circuit between the row and column wires. The microcontroller can then determine which key is pressed by checking which row and column wires are connected.

Why use a matrix keypad?

There are a number of reasons why you might want to use a matrix keypad in your project. Here are a few of the most common reasons:

  • Smaller size and footprint.
  • Reliability.
  • Cost savings.

What makes my design different from most others out there?

While the matrix keypad in its simplest form is constructed from only wires and switches, that simple approach can sometimes have some unwanted effects, especially when pressing multiple keys at the same time – a phenomenon called ghosting – where you get phantom keypresses. This is easily eliminated by adding a diode in series with each switch, usually on the row connection.

That single component fixes ghosting reliably but does not come without its own problems, the most important of these being that a keypad with diodes becomes “polarised” – current can only flow in a single direction through a switch. This can cause problems with some third-party libraries, as the designer of the keypad and the designer of the library very often has quite different ideas of what a row and a column mean in a keypad.

This is important, – here we go down the rabbit hole; in my understanding of the keypad scanning routine, a column runs from top to bottom, and a row from left to right. Keeping this in mind, the microcontroller will alternatively set each column HIGH, and configure each row as an input. When a key is pressed, current will flow from the specific column GPIO, through the switch, and into the Row GPIO, sending the input pin HIGH…

It is also possible to configure the columns as inputs, with internal pullups enabled, and have each Row pin as an output, configured to sink ( pull current to ground). This will cause the specific column to go low – thus identifying the pressed key…

These different ways of handling the problem of reading a key, and believe me, there are actually more variations, create a few unique problems. We may have to swap rows and columns as far as pin connections and firmware are concerned, as well as define a custom “keymap” to assign values to each key.

The Schematic

As we can see above, the schematic is very basic. 16 switches, 16 diodes and a single 8-way header pin. Pin 1 to 4 on the header is connected to Columns 1 to 4, and Pin 5 to 8 is connected to Rows 1 to 4.

The diodes prevent “ghosting currents from flowing into other keys in a row when multiple keys are pressed together. They also seem to help with other stray signals and interference.

The PCB

The PCB is a simple double-layer board. All components are mounted on the top layer.

To limit interference from stray signals, I have routed rows and columns on opposite sides of the PCB where possible.

Manufacturing

I choose PCBWay for my PCB manufacturing.
This month, PCBWay is also celebrating its 9th anniversary, and that means that there are quite a lot of very special offers available.


Why? What makes them different from the rest?
PCBWay‘s business goal is to be the most professional PCB manufacturer for prototyping and low-volume production work in the world. With more than a decade in the business, they are committed to meeting the needs of their customers from different industries in terms of quality, delivery, cost-effectiveness and any other demanding requests. As one of the most experienced PCB manufacturers and SMT Assemblers in China, they pride themselves to be our (the Makers) best business partners, as well as good friends in every aspect of our PCB manufacturing needs. They strive to make our R&D work easy and hassle-free.

How do they do that?

PCBWay is NOT a broker. That means that they do all manufacturing and assembly themselves, cutting out all the middlemen, and saving us money.

PCBWay’s online quoting system gives a very detailed and accurate picture of all costs upfront, including components and assembly costs. This saves a lot of time and hassle.

PCBWay gives you one-on-one customer support, that answers you in 5 minutes ( from the Website chat ), or by email within a few hours ( from your personal account manager). Issues are really resolved very quickly, not that there are many anyway, but, as we are all human, it is nice to know that when a gremlin rears its head, you have someone to talk to that will do his/her best to resolve your issue as soon as possible.

Find out more here

Assembly

This project does not require a lot of specialised equipment to assemble. The SMD diodes can easily be soldered by hand, the same with the switches and 8-way header. In my case, I chose to solder the header pins on the back of the PCB, that way, I can later use the keypad in a suitable enclosure without having wires in the way.

Testing and Coding

Testing a matric keypad can sometimes be a challenge. In my case, a multimeter with clip leads, set to diode mode, with the leads connected to each column and row in turn, while minding the polarity, and pressing each key in that row in turn, verified continuity.

With that done, it was time to put my trusted Cytron Maker Uno to work, as this Arduino Clone has the added benefit of having LEDs on each of the GPIO lines, thus making it very easy to see what is happening.

I made use of a Keypad library in the Arduino IDE, mainly to cut down on the amount of coding, but also because it is easier to use a working piece of code, and then adapt that to my keypad.

Detailed Code examples for ESPHome are available on Patreon

/* @file CustomKeypad.pde
|| @version 1.0
|| @author Alexander Brevig
|| @contact alexanderbrevig@gmail.com
||
|| @description
|| | Demonstrates changing the keypad size and key values.
|| #

Edited by MakerIoT2020, with minor changes to make it function correctly with my custom keypad.
I have also added a simple LED blinking routine to show that the Arduino is “alive” and that the Keypad code seems to be NON-blocking – which is quite important to me.

*/
#include <Keypad.h>

const byte ROWS = 4; //four rows
const byte COLS = 4; //four columns
//define the symbols on the buttons of the keypads
char hexaKeys[ROWS][COLS] = {
{‘1′,’4′,’7′,’*’},
{‘2′,’5′,’8′,’0’},
{‘3′,’6′,’9′,’#’},
{‘A’,’B’,’C’,’D’}
};
byte rowPins[ROWS] = {2,3,4,5}; //connect to the row pinouts of the keypad
byte colPins[COLS] = {6,7,8,9}; //connect to the column pinouts of the keypad
/*
* Due to libraries being written by different people, and our definitions about
* what a row and a column are, is different, note that the rows in the code
* is actually the columns on my PCB. This becomes true, due to the fact that my
* PCB has Diodes on each switch, and that thus makes current flow in only one
* direction///
*
* it also has the “side effect” that keys are layout in a strange “mirrored” and
* rotated way in the firmware.
* it does however NOT affect the correct operation of the Keypad Module at all
*
*/

const int LEDPin = LED_BUILTIN;
int ledState = LOW;
unsigned long prevmillis = 0;
const long interval = 1000;

//initialize an instance of class NewKeypad
Keypad customKeypad = Keypad( makeKeymap(hexaKeys), rowPins, colPins, ROWS, COLS);

void setup(){
Serial.begin(115200);
pinMode(LEDPin,OUTPUT);
}

void loop(){
unsigned long currentMillis = millis();
if (currentMillis – prevmillis >= interval) {
prevmillis = currentMillis;
if (ledState == LOW) {
ledState = HIGH;
} else {
ledState = LOW;
}
digitalWrite(LEDPin,ledState);
}
char customKey = customKeypad.getKey();

if (customKey){
Serial.println(customKey);
}
}

This code works very well and allowed me to verify the correct operation of the keypad.

In conclusion

Making my own Keypad Module is a project that is long overdue. I have purchased a few online over the years, and as they were mostly of the membrane type, they did not last very long – it must be something to do with the ultra-cheap flexible PCB ribbon connector, since a quality membrane keypad can be quite expensive, and usually lasts quite a long time.

Having my own module available to experiment with will allow me to do some long-delayed improvements to many of my IoT modules. That code, mostly YAML for ESPHome, will be made available on Patreon.