Key programming is one of the most popular functions of the Delphi DS150E. With this device, users can program new keys, repair existing keys, and even clone keys. The DS150E supports a wide range of vehicle makes and models, including those with advanced immobilizer systems.
Here are detailed, step-by-step instructions for key programming with Delphi DS150E:
In the world of automotive locksmithing and key programming, having the right tools and software is essential for success. One of the most popular and reliable tools on the market is the Delphi DS150E, a powerful diagnostic tool that offers a range of functions, including key programming. In this article, we will explore the ins and outs of key programming with Delphi DS150E, including its features, benefits, and step-by-step instructions on how to program keys using this device.
Key programming with Delphi DS150E is a straightforward and efficient process that offers a range of benefits for locksmiths and technicians. With its wide vehicle coverage, accuracy, and reliability, the DS150E is an essential tool for anyone involved in automotive key programming. By following the step-by-step instructions outlined in this article, users can confidently program new keys, repair existing keys, and clone keys using the Delphi DS150E. Whether you're a seasoned locksmith or just starting out, the Delphi DS150E is an investment worth considering.
This LMC simulator is based on the Little Man Computer (LMC) model of a computer, created by Dr. Stuart Madnick in 1965. LMC is generally used for educational purposes as it models a simple Von Neumann architecture computer which has all of the basic features of a modern computer. It is programmed using assembly code. You can find out more about this model on this wikipedia page.
You can read more about this LMC simulator on 101Computing.net.
Note that in the following table “xx” refers to a memory address (aka mailbox) in the RAM. The online LMC simulator has 100 different mailboxes in the RAM ranging from 00 to 99.
| Mnemonic | Name | Description | Op Code |
| INP | INPUT | Retrieve user input and stores it in the accumulator. | 901 |
| OUT | OUTPUT | Output the value stored in the accumulator. | 902 |
| LDA | LOAD | Load the Accumulator with the contents of the memory address given. | 5xx |
| STA | STORE | Store the value in the Accumulator in the memory address given. | 3xx |
| ADD | ADD | Add the contents of the memory address to the Accumulator | 1xx |
| SUB | SUBTRACT | Subtract the contents of the memory address from the Accumulator | 2xx |
| BRP | BRANCH IF POSITIVE | Branch/Jump to the address given if the Accumulator is zero or positive. | 8xx |
| BRZ | BRANCH IF ZERO | Branch/Jump to the address given if the Accumulator is zero. | 7xx |
| BRA | BRANCH ALWAYS | Branch/Jump to the address given. | 6xx |
| HLT | HALT | Stop the code | 000 |
| DAT | DATA LOCATION | Used to associate a label to a free memory address. An optional value can also be used to be stored at the memory address. |