Made changes to ch04.asciidoc

ch04.asciidoc

@@ -473,7 +473,7 @@ include::code/key-to-address-ecc-example.py[]
 ----
 ====
 
-Here's the output from running this code:
+<<key-to-address_script_run>> shows  the output from running this code.
 
 [[key-to-address_script_run]]
 .Running key-to-address-ecc-example.py
@@ -507,10 +507,10 @@ Compressed Bitcoin Address (b58check) is:
 ====
 
 
-Here's another example, using the Python ECDSA library for the Elliptic Curve math and without using any specialized bitcoin libraries:
+<<ec_math>> is another example, using the Python ECDSA library for the elliptic curve math and without using any specialized bitcoin libraries.
 
 [[ec_math]]
-.A script demonstrating Elliptic Curve math used for bitcoin keys
+.A script demonstrating elliptic curve math used for bitcoin keys
 ====
 [source, python]
 ----
@@ -518,7 +518,7 @@ include::code/ec-math.py[]
 ----
 ====
 
-Running the script:
+<<ec_math_run>> shows the output produced by running this script.
 
 [[ec_math_run]]
 .Installing the Python ECDSA library and running the ec_math.py script
@@ -545,7 +545,7 @@ Another method for making keys is _deterministic key generation_. Here you deriv
 
 [TIP]
 ====
-Wallets contain keys, not coins. The coins are stored on the blockchain in the form of transaction-outputs (often noted as _vout_ or _txout_). Each user has a wallet containing keys. Wallets are really keychains containing pairs of private/public keys (See XREF-public_key]). Users sign transactions with the keys, thereby proving they own the transaction outputs (their coins). 
+Wallets contain keys, not coins. The coins are stored on the blockchain in the form of transaction-outputs (often noted as _vout_ or _txout_). Each user has a wallet containing keys. Wallets are really keychains containing pairs of private/public keys (see XREF-public_key]). Users sign transactions with the keys, thereby proving they own the transaction outputs (their coins). 
 ====
 
 [[random_wallet]]