Secure Boot ¶
Applies to the Jetson AGX Orin series, the Jetson Xavier NX series, and the Jetson AGX Xavier series.
NVIDIA ® Jetson™ Linux provides boot security using the Secure Boot package. Secure Boot prevents execution of unauthorized boot codes through the chain of trust. The root-of-trust is an on-die BootROM code that authenticates boot codes such as BCT, Bootloader, and warm boot vector using Public Key Cryptography (PKC) keys stored in write-once-read-multiple fuse devices. On Jetson platforms that support Secure Boot Key (SBK), you can use it to encrypt Bootloader images.
NVIDIA SoCs contain multiple fuses that control different items for security and boot.
The Secure Boot package contains program scripts/tools and instructions to provide security services during the booting.
Overall Fusing and Signing Binaries Flow ¶
The Secure Boot process with PKC and SBK requires you to:
-
Install the Secure Boot package.
-
Generate an RSA key pair.
-
Prepare an SBK key.
-
Prepare KEK keys.
-
Prepare the Fuse Configuration file.
-
Burn fuses using
odmfuse.sh
script with a Fuse Configuration file. -
Flash the device with secured images (using
flash.sh
with-u
-v
options).
Installing the Secure Boot Package ¶
The Secure Boot Package includes scripts/tools to facilitate burning of security fuses and flashing of encrypted/signed images to the Jetson devices.
Prerequisites ¶
-
An X86 host running Ubuntu 18.04 LTS, or 20.04 LTS.
-
libftdi-dev
for USB debug port support. -
openssh-server
package for OpenSSL. -
Full installation of the latest Jetson Linux release on the host.
-
A USB cable connecting the Jetson device to the host.
-
If necessary, a USB cable that connects the Jetson device’s debug serial port to the host.
Install Secure Boot Package ¶
-
Download the version of the Secure Boot package for your platform and release of Jetson Linux from the release page.
Here is the link to the release page:
https://developer.nvidia.com/embedded/jetson-linux
-
Go to the directory that contains the
Linux_for_Tegra/
directory. (This directory is created when the Jetson Board Support Package is installed.) -
To untar the downloaded file, enter the following command:
$ tar xvjf secureboot_
.tbz2 This command overlays the contents of the file on the
Linux_for_Tegra/
directory.
Fuses and Security ¶
NVIDIA SoCs contain multiple fuses that control different items for security and boot. Once a fuse bit is set to 1, you cannot change its value back to 0. For example, a fuse value of 1 (0x01) can be changed to 3 (0x03) or 5 (0x05), but not to 4 (0x4) because bit 0 is already programmed to 1.
After the
SecurityMode
(also known as
odm_production_mode
) fuse is burned with a value of 0x1, all additional fuse write requests will be blocked.
However, some of the ODM fuses are still writable. For more details, refer to the specific SoC fuses documents.
To burn fuses, you can use the
odmfuse.sh
script with a fuse configuration file.
The fuse configuration file is an XML file that contains the fuse data to be burned.
Fuse Configuration File ¶
The fuse configuration file, which is an XML file, contains the fuse data, a list of fuses, and the value to be burned in each fuse.
The odmfuse.sh tool uses this XML file to program the fuses.
A fuse configuration file contains a
The following template shows the format of the file:
. . .
Where:
is the name of a fuse. Supported fuse names are listed in the SoC’s Reference Fuse Configuration File.
For Orin SoC, refer to Orin Reference Fuse Configuration File
For Xavier SoC, refer to Xavier Reference Fuse Configuration File
is the size of the fuse in bytes.
is the value to be burned into the fuse, with two hexadecimal digits per byte.
MagicId
of “0x45535546” is used by the target-binary and must not be changed.
odmfuse.sh
script burns fuses in the order that they appear in the fuse configuration file. If two or more fuses’ values are interdependent, the independent fuses must be specified
before
the dependent one so that they are burned first. That is, if the values that can be burned into fuse Y depend on the value of fuse X, the fuse configuration file must specify fuse X first and then Y. This way, the
odmfuse.sh
script will burn fuse X first.
Caution
The
odmfuse.sh
fuse burning tool does not check for dependencies, so specifying a dependent fuse before the fuse it depends on might render the target device inoperable. Check the fuse list’s order carefully before you burn the fuses.
Note
Although the fuse configuration file contains XML tags, it does not need the “” prolog defined by the XML standard. Fuse configurations might not have a prolog. If you want to run general purpose XML utilities on such a file, you might have to add a prolog.
Each SoC has its own specific fuses and fuse names.
For details on fuses and fuse names for each SoC, refer to the following documents:
-
For Jetson AGX Orin series: Jetson AGX Orin Series Fuse Specification Application Note
-
For Jetson Xavier NX series: Jetson Xavier NX Fuse Specification Application Note
-
For Jetson AGX Xavier series: Jetson AGX Xavier Series Fuse Programming Application Note
Note
These Application Note documents can be found in the following page:
https://developer.nvidia.com/embedded/downloads#?search=fuse
The following sections describe the Fuse Configuration Files for each SoC.
For Jetson Orin SoC, refer to Orin Reference Fuse Configuration File .
For Jetson Xavier SoC. refer to Xavier Reference Fuse Configuration File .
Jetson AGX Orin Fuse Configuration File ¶
Refer to Jetson AGX Orin Series Fuse Programming Application Note for the details on fuses and fuse names for Orin SoC.
Example Orin Fuse Configuration File to Program the RSA-3K Key ¶
Example fuse configuration file to enable Secure Boot with RSA-3K key:
Note
Jetson AGX Orin series targets only support RSA-3K key.
Note
The value above for “PublicKeyHash” is for demonstrations only.
Refer to
Generate PublicKeyHash value from an RSA key pair
for more information about generating the
PublicKeyHash
fuse value.
Example Orin Fuse Configuration File to Program the RSA-3K Key + SBK Key + OemK1 Key ¶
The following sample configuration file is used to enable the Secure Boot with RSA-3K key, the SBK key, and the OemK1 key:
Note
The values of
PublicKeyHash
,
SecureBootKey
, and
OemK1
above are for demonstrations only.
Refer to
Generate PublicKeyHash value from an RSA key pair
for more information about generating the
PublicKeyHash
fuse value.
Refer to
Prepare an SBK key
for more information about generating the
SecureBootKey
fuse value.
Refer to
Prepare K1/K2/KEK keys
for more information about generating the
OemK1
fuse value.
Orin Reference Fuse Configuration File ¶
The Orin Reference Fuse Configuration file lists all fuses that are supported by the Orin SoC.
All fuse values in the reference configuration file are enclosed in XML comments. To adapt the reference file for fusing, uncomment them and replace their “0xFFFF” placeholder values with the actual values for your target.
Here is the Orin Reference Fuse Configuration File for Jetson AGX Orin devices:
Jetson Xavier NX and Jetson AGX Xavier Fuse Configuration Files ¶
For details on hardware fuses and fuse names, refer to the following documents:
-
For Jetson Xavier NX series: Jetson Xavier NX Fuse Specification Application Note
-
For Jetson AGX Xavier series: Jetson AGX Xavier Series Fuse Programming Application Note
Example Xavier Fuse Configuration File to Program the RSA-2K Key ¶
The following sample configuration file is used to enable Secure Boot with RSA-2K key:
Note
Jetson AGX Xavier series and Jetson Xavier NX series targets support both RSA-2K and RSA-3K key.
Note
The value above for
PublicKeyHash
is for demonstrations only.
Refer to
Generate PublicKeyHash value from an RSA key pair
for more information about generating the
PublicKeyHash
fuse value.
Example Xavier Fuse Configuration File to Program the RSA-3K Key + SBK Key + KEK Key ¶
The following sample configuration file is used to enable Secure Boot with RSA-3K key, SBK key and KEK keys:
Note
The values above of
PublicKeyHash
,
SecureBootKey
,
Kek0
and
Kek1
are for demonstrations only.
Refer to
Generate PublicKeyHash value from an RSA key pair
for more information about generating the
PublicKeyHash
fuse value.
Refer to
Prepare an SBK key
for more information about generating the
SecureBootKey
fuse value.
Refer to
Prepare K1/K2/KEK keys
for more information about generating the
Kek0
and
Kek1
fuse values.
Xavier Reference Fuse Configuration File ¶
The Xavier Reference Fuse Configuration file lists all fuses that are supported by Xavier SoC.
All fuse values in the reference configuration file are enclosed in XML comments. To adapt the reference file for fusing, uncomment them and replace their “0xFFFF” placeholder values with the actual values for your target.
Following shows the Xavier Reference Fuse Configuration file for Jetson Xavier NX and Jetson AGX Xavier devices:
Generate An RSA Key Pair ¶
Secure Boot requires an RSA key pair whose length is 2048 bits (RSA 2K) or 3072 bits (RSA 3K).
Note
The 3072-bit RSA key option is supported on Jetson AGX Orin series, Jetson Xavier NX series and Jetson AGX Xavier series.
The 2048-bit RSA key option is no longer supported on Jetson AGX Orin series.
-
Enter one of the following commands:
-
To generate an RSA 2K key:
$ openssl genrsa -out rsa_priv.pem 2048
-
To generate an RSA 3K key:
$ openssl genrsa -out rsa_priv.pem 3072
OpenSSL generates the key file, named
rsa_priv.pem
. -
-
Rename and save the key file.
The key file is used to burn fuses and sign boot files for Jetson devices.
Caution
The security of your device depends on how securely you keep the key file.
Note
To generate a truly random number key, use the Hardware Security Module (HSM).
Generate
PublicKeyHash
value from an RSA key pair
¶
Instead of fusing the public key of the RSA key pair, only the hash of the public key is burned to the “PublicKeyHash” fuse field.
You can use
tegrakeyhash
program to generate
PublicKeyHash
value:
sudo ./tegrakeyhash --pkc --chip
Where:
is the RSA key pair (.pem file) file
is 0x23 for Jetson AGX Orin series; 0x19 for Jetson NX Xavier series and Jetson AGX Xavier series
The hexadecimal value shown on the screen after
tegra-fuse
format
(big-endian):
can be used directly as
PublicKeyHash
fuse data of a Fuse Configuration file.
Note
tegrakeyhash
program generates 64 bytes of
PublicKeyHash
value for Orin SoC (chip_id of 0x23).
tegrakeyhash
program generates 32 bytes of
PublicKeyHash
value for Xavier SoC (chip_id of 0x19).
Here are some sample outputs after running
tegrakeyhash
to generate
PublicKeyHash
:
$ sudo ./tegrakeyhash --pkc rsa_priv-3k.pem --chip 0x23
Key size is 384 bytes
sha512 hash:
bytes:
0x18, 0xe9, 0x84, 0xf7, 0xd7, 0x9f, 0x7a, 0x18,
0x50, 0x39, 0xec, 0x41, 0x3e, 0xd2, 0xff, 0x86,
0x22, 0x7c, 0x8f, 0x0b, 0xe6, 0x39, 0xed, 0xde,
0x0c, 0xf2, 0x3a, 0xb1, 0xf7, 0x91, 0x0b, 0x75,
0x9e, 0xde, 0x8f, 0xb0, 0xc2, 0x0d, 0x02, 0xc6,
0x8d, 0xeb, 0x04, 0xa7, 0x52, 0x26, 0xd6, 0x32,
0xf9, 0xfe, 0x24, 0xc7, 0x1d, 0xad, 0x4b, 0x30,
0x2a, 0xcd, 0xba, 0x13, 0xdb, 0x65, 0x81, 0x30,
tegra-fuse format (big-endian):
0x18e984f7d79f7a185039ec413ed2ff86227c8f0be639edde0cf23ab1f7910b759ede8fb0c20d02c68deb04a75226d632f9fe24c71dad4b302acdba13db658130
fuse bypass format:
FAB_ENTRY(PUBLIC_KEY0, PUBLIC_KEY0, 0xf784e918),
FAB_ENTRY(PUBLIC_KEY1, PUBLIC_KEY1, 0x187a9fd7),
FAB_ENTRY(PUBLIC_KEY2, PUBLIC_KEY2, 0x41ec3950),
FAB_ENTRY(PUBLIC_KEY3, PUBLIC_KEY3, 0x86ffd23e),
FAB_ENTRY(PUBLIC_KEY4, PUBLIC_KEY4, 0x0b8f7c22),
FAB_ENTRY(PUBLIC_KEY5, PUBLIC_KEY5, 0xdeed39e6),
FAB_ENTRY(PUBLIC_KEY6, PUBLIC_KEY6, 0xb13af20c),
FAB_ENTRY(PUBLIC_KEY7, PUBLIC_KEY7, 0x750b91f7),
FAB_ENTRY(PUBLIC_KEY8, PUBLIC_KEY8, 0xb08fde9e),
FAB_ENTRY(PUBLIC_KEY9, PUBLIC_KEY9, 0xc6020dc2),
FAB_ENTRY(PUBLIC_KEY10, PUBLIC_KEY10, 0xa704eb8d),
FAB_ENTRY(PUBLIC_KEY11, PUBLIC_KEY11, 0x32d62652),
FAB_ENTRY(PUBLIC_KEY12, PUBLIC_KEY12, 0xc724fef9),
FAB_ENTRY(PUBLIC_KEY13, PUBLIC_KEY13, 0x304bad1d),
FAB_ENTRY(PUBLIC_KEY14, PUBLIC_KEY14, 0x13bacd2a),
FAB_ENTRY(PUBLIC_KEY15, PUBLIC_KEY15, 0x308165db),
Prepare an SBK key ¶
An SBK key is used to encrypt Bootloader components. The same SBK key has to be fused to the Jetson’s SoC fuses, so the key can be used to decrypt the Bootloader components when the Jetson device boots up.
Note
You can only use the SBK key with the PKC key. The encryption mode that uses these two keys together is called SBKPKC.
The Orin SoC requires an SBK key be of eight 32-bit words (32 bytes). The Xavier SoC requires an SBK key be four 32-bit words (16 bytes).
The SBK key file is stored in big-endian hexadecimal format.
Here is an example of a 16-byte SBK key file:
0x12345678 0x9abcdef0 0xfedcba98 0x76543210
This type of file format is used in
flash.sh
command with
-v
option.
The same SBK representation used in the “SecureBootKey” fuse value field of a Fuse Configuration XML file is:
0x123456789abcdef0fedcba9876543210
Note
Hexadecimal numbers must be presented in big-endian format. The leading 0x or 0X can be omitted. The Jetson Secure Boot software converts the big-endian hexadecimal format to the format that the Jetson device expects. All standard OpenSSL utilities output in big-endian format.
We recommend that you use the Hardware Security Module (HSM) to generate a truly random number for an SBK key.
Caution
The security of your device depends on how securely you keep the key file.
Prepare K1/K2/KEK keys ¶
The K1/K2/KEK keys are used for other security application, such as disk encryption/decryption, you must prepare these keys and other ODM fuse bits as described in the documentation for the other security application.
For Jetson Orin SoC, the fuse key names are
OemK1
and
OemK2
, and the key length is 32 bytes.
For Jetson Xavier SoC, the fuse key names are
Kek0
,
Kek1
,
Kek2
, for which the key length is 16 bytes.
Kek256
is a combination of
Kek0
and
Kek1
with a key length of 32 bytes.
These keys must be presented in Hexadecimal numbers and must be in the big-endian format.
Note
The leading 0x or 0X of a hexadecimal number can be omitted. The Jetson Secure Boot software converts the big-endian hexadecimal format to the format that the Jetson device expects.
These keys consist of eight (or four) 32-bit words stored in a file in the big-endian hexadecimal format.
Here is an example of an
OemK1
key file:
0x11223344 0x55667788 0x99aabbcc 0xddeeff00 0xffeeddcc 0xbbaa9988 0x77665544 0x33221100
The same key representation in the
OemK1
fuse value field in the Fuse Configuration XML file is:
0x112233445566778899aabbccddeeff00ffeeddccbbaa99887766554433221100
Note
We recommend that you use the HSM to generate a truly random number for KEK keys.
Caution
The security of your device depends on how securely you keep these key files.
Prepare the Fuse Configuration file ¶
To modify the SoC’s Reference Fuse Configuration file, uncomment the fuses you need, and enter information in the correct fuse data fields for your target Jetson device.
The next section provides information about how to burn fuses with the prepared Fuse Configuration file.
Caution
The security of your device depends on how securely you keep the Fuse Configuration file.
Burn Fuses with the Fuse Configuration file ¶
After the Fuse Configuration file is prepared, you can burn fuses using
odmfuse.sh
(-X option) script with the Fuse Configuration file:
sudo ./odmfuse.sh -X -i
If a Jetson board was previously burned with a PKC key
odmfuse.sh
command with -k option:
sudo ./odmfuse.sh -X -i -k
Where:
is the fuse configuration XML file.
is 0x23 for Jetson AGX Orin; 0x19 for Jetson Xavier NX and Jetson AGX Xavier.
is the RSA key pair (.pem file) that was fused to the board before.
is the name of the configuration for your Jetson device and carrier board; see the table in Jetson Modules and Configurations .
Note
Fuse burning operations are high-risk because they cannot be reversed. NVIDIA strongly recommends that you use the
--test
option to verify fuse burning operations before you perform them.
When you add
--test
to an
odmfuse.sh
command, the command performs pre-burn processing and verification, but it does not actually burn the fuse. If the command reports the results you want, you can re-enter the command without
--test
and burn the fuse with greater confidence that you are doing it correctly.
Sign and Flash Secured Images ¶
The procedures described in this section use the following placeholders in their commands:
Sign and Flash Secured Images in One Step ¶
For Jetson AGX Orin series ¶
-
Navigate to the directory where you installed Jetson Linux.
-
Place the Jetson device into Recovery mode.
-
Enter the following command:
$ sudo ./flash.sh -u
mmcblk0p1
Note
If
-u
command option is omitted, all images flashed to the Jetson device are not signed.
Caution
The PKC key file must not be placed under the bootloader directory.
For Jetson Xavier NX series and Jetson AGX Xavier series ¶
-
Navigate to the directory where you installed Jetson Linux.
-
Place the Jetson device into Recovery mode.
-
Enter the following command:
$ sudo ./flash.sh -u
[-v ] mmcblk0p1
Note
If
-v
command option is specified,
-u
command option must be specified also.
If
-v
command option is omitted, all images flashed to the Jetson device are not encrypted.
If
-u
command option is omitted, all images flashed to the Jetson device are not signed.
Caution
None of the PKC key file and SBK key file can be placed under the bootloader directory.
Sign and Flash Secured Images in Separate Steps ¶
-
Sign/encrypt the boot files:
$ sudo ./flash.sh --no-flash -u
[-v ] mmcblk0p1 Note
If
-v
command option is specified,-u
command option must be specified also.If
-v
command option is omitted, all images flashed to the Jetson device are not encrypted.If
-u
command option is omitted, all images flashed to the Jetson device are not signed. -
Flash the generated encrypted/signed images:
$ cd bootloader $ sudo bash ./flashcmd.txt
Note
Ensure that you place the Jetson device into Recovery mode before executing
flashcmd.txt
command.
Legacy Support of Secure Boot for Xavier SoC ¶
Applies to the Jetson Xavier NX series and the Jetson AGX Xavier series only.
The following sections describe the legacy support for the Jetson Xavier NX and the Jetson AGX Xavier series only.
The following table describes user-programmable fuses that are related to Secure Boot for Xavier Soc.
Software and configuration fuses related to Secure Boot for NVIDIA ® Jetson Xavier™ NX series and NVIDIA ® Jetson AGX Xavier™ series |
||
---|---|---|
Bit size |
Name |
Default value set by
|
1 |
odm_production_mode |
0x1. |
256 |
public_key_hash |
RSA public key hash. |
128 |
secure_boot_key* |
Secure Boot Key (SBK): AES encryption key for encrypting bootloader. |
128 |
KEK0* |
Four 32-bit register named KEK00 through KEK03. |
128 |
KEK1* |
Four 32-bit registers named KEK10 through KEK13. |
256 |
KEK256 |
Not a distinct fuse; addresses KEK0 and KEK1 as a single 256-bit fuse. |
128 |
KEK2* |
Four 32-bit registers named KEK20 through KEK23. |
* You can use
|
Here are the fuses that are handled by the user:
Bit size |
Name |
Default value set by odmfuse.sh |
---|---|---|
1 |
jtag_disable |
0x0: JTAG is enabled (the default). 0x1: JTAG is disabled. |
256 |
odm_reserved |
Reserved fuses for the customer use.
They are organized as 8 consecutive
32-bit fuses,
|
4 |
odm_lock |
Each bit set disables the write for the corresponding 32-bit odm_reserved fuses.
For example: 0x2 locks bits 32−63 of
|
8 |
sec_boot_dev_cfg |
Depending on
|
24 |
sw_reserved |
A bit map of configuration options. Bits not described here are reserved.
Bits 2-0:
Bit 3:
Bit 5:
Bit 23: 1=disable RCM mode |
For details on hardware fuses and fuse names, refer to the following documents:
-
For Jetson Xavier NX series: Jetson Xavier NX Fuse Specification Application Note
-
For Jetson AGX Xavier series: Jetson AGX Xavier Series Fuse Programming Application Note
The following table describes the fuse name aliases that are recognized by
tegraflash
..
Fuse Name Aliases Recognized by tegraflash for Jetson Xavier NX series and Jetson AGX Xavier series |
|
---|---|
Name |
tegraflash Alias and Notes |
odm_production_mode |
SecurityMode |
public_key_hash |
PublicKeyHash |
secure_boot_key |
Secure BootKey |
Security_info |
BootSecurityInfo |
Key_encryption_key_0 |
Kek0 |
Key_encryption_key_1 |
Kek1 |
Key_encryption_key_256 |
Kek256 |
Key_encryption_key_2 |
Kek2 |
jtag_disable |
JtagDisable |
odm_reserved0, odm_reserved1,… odm_reserved7 |
Customer programmable fuses;
remain programmable after
Default value (when no reserved ODM fuses have been programmed) is all zeros. One intended application of these fuses is software version revocation. You may use them for other purposes at your discretion. |
odm_reserved8,… odm_reserved11 |
Reserved for use by NVIDIA. Do not use these fuses. Customer programming of these can result in boot failures and unexpected behavior. |
odm_lock |
Each bit disables further
changes to one of the
|
sec_boot_dev_cfg |
|
sw_reserved |
|
Burning PKC, KEK, and SBK Fuses ¶
To burn the PKC, KEK and SBK fuses by using a private key file PEM format:
-
Navigate to the host directory where you installed Jetson Linux.
-
Put the Jetson device into Force Recovery Mode.
-
Burn the fuse using the script
odmfuse.sh
. See odmfuse.sh Option Usage for illustrations of common operations.
Note
odmfuse.sh
uses OpenSSL to burn PKC fuses.
odmfuse.sh Options ¶
For fuses other than PKC key and
odm_production_mode
fuses,
odmfuse.sh allows you to program ODM fuses that are completely at
your discretion. Skip this topic if you do not plan to modify these
fuses.
These are the
odmfuse.sh
command line options that blow ODM fuses:
Option |
Description |
---|---|
-d 0xXXXX |
Sets
|
-disable-jtag |
Disables JTAG. Use this option to block use of the JTAG debugger. |
-l 0xX |
Sets
For example, setting
|
–odm_reserved[0:7] |
Sets
|
-p |
Sets production mode. |
-r 0xXX |
Sets
Bits 7-6: Reserved. Bit 5: Enable_watchdog. Bit 4: Reserved.
Bit 3:
Bits 2-0:
|
-S |
Sets the Secure Boot key used to
encrypt Bootloader and the TOS. The
content of
This key must be used along with PKC key. |
–noburn |
Prepares the fuse blob to be used repeatedly on the factory floor.
This option generates
After
|
–KEK0 –KEK1
–KEK2 |
Pathname of the key encryption key file that other security applications are to use to encrypt and decrypt keys. The content of the file must be a single 128-bit big-endian number in hexadecimal format. |
–KEK256 |
Pathname of the 256-bit Key Encryption Key file that the high-level security application will use to encrypt the application keys. The content of the file must be a single 256-bit big-endian number in hexadecimal format. |
–auth |
Indicates the board’s current authentication status.
Possible
This option is only used when running
To run
Examples:
|
–test |
Prevents the script from actually burning fuses. Pre-burn processing and tests are performed as usual. This option is normally used for fuse burning tests, since fuse values cannot be changed once they are burned. |
Non-Destructive Testing for Fuse Burning Operations ¶
Fuse burning operations are high-risk because they cannot be reversed.
NVIDIA strongly recommends that you use the
--test
option to verify fuse
burning operations before you perform them.
When you add
--test
to an
odmfuse.sh
command, the command performs
pre-burn processing and verification, but it does not actually burn the
fuse. If the command reports the results you want, you can enter the command
again without
--test
and burn the fuse with greater confidence that
you are doing it correctly.
odmfuse.sh Option Usage ¶
-
To fuse PKC HASH from the .pem file with JTAG enabled:
$ sudo ./odmfuse.sh -i
-p -k --KEK[0-2] -S -
To fuse PKC HASH from the .pem file with JTAG disabled:
$ sudo ./odmfuse.sh -i
-p -k --KEK[0-2] -S --disable-jtag -
To burn a secure fuse with PKC, SBK, and KEK2:
$ sudo ./odmfuse.sh -i
-p -k -S --KEK2 -
To burn a secure fuse with PKC and KEK2:
$ sudo ./odmfuse.sh -i
-p -k --KEK2
Where:
Signing and Flashing with initrd Using the l4t_initrd_flash.sh Script ¶
-
Place the Jetson device into Force Recovery mode.
-
To sign the image, run the command:
$ sudo ./tools/kernel_flash/l4t_initrd_flash.sh --no-flash -u
[-v ] Where (in addition to the placeholders described in Placeholders Used in the Procedures ):
-
BOARD
. (See the table in Jetson Modules and Configurations -
-
-
To flash the target device, run the following command:
$ sudo ./tools/kernel_flash/l4t_initrd_flash.sh --flash-only -u
[-v ]
Where
and
are the same as in step 2, above.